CN109963953A - Master alloy metal matrix nanocomposite and its production method - Google Patents
Master alloy metal matrix nanocomposite and its production method Download PDFInfo
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- CN109963953A CN109963953A CN201780070904.3A CN201780070904A CN109963953A CN 109963953 A CN109963953 A CN 109963953A CN 201780070904 A CN201780070904 A CN 201780070904A CN 109963953 A CN109963953 A CN 109963953A
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- B22F1/00—Metallic powder; Treatment of metallic powder, e.g. to facilitate working or to improve properties
- B22F1/05—Metallic powder characterised by the size or surface area of the particles
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F1/00—Metallic powder; Treatment of metallic powder, e.g. to facilitate working or to improve properties
- B22F1/16—Metallic particles coated with a non-metal
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F1/00—Metallic powder; Treatment of metallic powder, e.g. to facilitate working or to improve properties
- B22F1/17—Metallic particles coated with metal
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F1/00—Metallic powder; Treatment of metallic powder, e.g. to facilitate working or to improve properties
- B22F1/18—Non-metallic particles coated with metal
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F7/00—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression
- B22F7/02—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression of composite layers
- B22F7/04—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression of composite layers with one or more layers not made from powder, e.g. made from solid metal
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- C—CHEMISTRY; METALLURGY
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- C—CHEMISTRY; METALLURGY
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- C—CHEMISTRY; METALLURGY
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- C22C21/02—Alloys based on aluminium with silicon as the next major constituent
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- C22C32/00—Non-ferrous alloys containing at least 5% by weight but less than 50% by weight of oxides, carbides, borides, nitrides, silicides or other metal compounds, e.g. oxynitrides, sulfides, whether added as such or formed in situ
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B22F7/00—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression
- B22F7/02—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression of composite layers
- B22F7/04—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression of composite layers with one or more layers not made from powder, e.g. made from solid metal
- B22F2007/042—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression of composite layers with one or more layers not made from powder, e.g. made from solid metal characterised by the layer forming method
- B22F2007/045—Manufacture of composite layers, workpieces, or articles, comprising metallic powder, by sintering the powder, with or without compacting wherein at least one part is obtained by sintering or compression of composite layers with one or more layers not made from powder, e.g. made from solid metal characterised by the layer forming method accompanied by fusion or impregnation
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F2301/00—Metallic composition of the powder or its coating
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B22F—WORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
- B22F2302/00—Metal Compound, non-Metallic compound or non-metal composition of the powder or its coating
- B22F2302/10—Carbide
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B22F2998/00—Supplementary information concerning processes or compositions relating to powder metallurgy
- B22F2998/10—Processes characterised by the sequence of their steps
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
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- B22F2999/00—Aspects linked to processes or compositions used in powder metallurgy
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- C—CHEMISTRY; METALLURGY
- C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
- C22C—ALLOYS
- C22C32/00—Non-ferrous alloys containing at least 5% by weight but less than 50% by weight of oxides, carbides, borides, nitrides, silicides or other metal compounds, e.g. oxynitrides, sulfides, whether added as such or formed in situ
- C22C32/0047—Non-ferrous alloys containing at least 5% by weight but less than 50% by weight of oxides, carbides, borides, nitrides, silicides or other metal compounds, e.g. oxynitrides, sulfides, whether added as such or formed in situ with carbides, nitrides, borides or silicides as the main non-metallic constituents
- C22C32/0052—Non-ferrous alloys containing at least 5% by weight but less than 50% by weight of oxides, carbides, borides, nitrides, silicides or other metal compounds, e.g. oxynitrides, sulfides, whether added as such or formed in situ with carbides, nitrides, borides or silicides as the main non-metallic constituents only carbides
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
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Abstract
Some modifications provide a kind of metal matrix nanocomposite composition comprising metalliferous micro particles and nanoparticle, wherein the nano particle and/or be physically located on the surface of the micro particles, and wherein the nanoparticle throughout the composition with three-dimensional construction consolidation.The composition may be used as the ingot for producing metal matrix nanocomposite.Other modifications provide a kind of functionally graded metal matrix matter nanocomposite, it includes metal-matrix phase and containing the reinforced phase of nanoparticle, wherein the nanocomposite contains the concentration gradient of the nanoparticle.The nanocomposite can by or be converted into master alloy.The method that other modification offers prepare the method for metal matrix nanocomposite, prepare the method for functionally graded metal matrix matter nanocomposite and prepare master alloy metal matrix nanocomposite.The metal matrix nanocomposite can have cast microstructure.The method of disclosure enables the various loads of the nanoparticle in metal matrix nanocomposite to have a variety of compositions.
Description
Priority data
This international patent application requires the U.S. Provisional Patent Application No. 62/422,925 submitted on November 16th, 2016;
The U.S. Provisional Patent Application No. 62/422,930 that on November 16th, 2016 submits;Face with the U.S. submitted on November 16th, 2016
When number of patent application 62/422,940;And the U.S. Patent Application No. 15/808,878 submitted on November 9th, 2017 is preferential
Power, each of these patent applications are incorporated herein by reference hereby.
Technical field
The present disclosure relates generally to metal matrix nanocomposite and its preparation and application.
Background technique
Metal matrix nanocomposite is due to being capable of providing different rigidity, strength-weight ratio, high-temperature behavior and hardness
Combination and cause sizable concern.Metal matrix nanocomposite has extensive commercial use, including high abrasion
Alloy system, creep resistant alloy, high temperature alloy and radiation hardness alloy with improvement mechanical property.
It has difficulties currently, preparing metal matrix nanocomposite, the height including processing cost and equipment rapidoprint
Capital investment.Keep the effective ways of evenly dispersed nanoparticle reinforced phase considerably less in metal matrix, especially molten
In body processing.The reinforced phase reactivity of nanoscale enhancing and particle agglomeration limit the nano combined material of the metal matrix produced at present
The strengthening effect of material.
Wish to produce the inexpensive approach of these High performance nanometer composite materials, the nano combined material including low volume fraction
The nanocomposite (nanocomposite for containing various concentration nanoparticles) of material and high-volume fractional.
The method of production low volume fraction nanocomposite is only limitted to the original position in high degree of specificity alloy system at present
Reaction mechanism.These include oxide dispersion intensifying copper and steel, wherein oxide forming agent (such as aluminium) be introduced into alloy so as to
It removes the oxygen of dissolution and forms nano-oxide.Similar technology can be used for nitride and carbide.These technologies need big
The control climate and temperature of amount control, to ensure that the nucleation rate in material is stablized, from without being significantly roughened.Therefore,
These materials are very expensive and geometry is limited.Due to diffusion, the dynamics of nucleation and growth, geometry must be opposite
It is uniform thin, to allow uniform compound to be formed.Thick material part needs the longer time that can just material center be made to start into
Core oxide, nitride or carbide.It is thus impossible to have the material of uniform properties by thickness preparation.
A large amount of loads of ex situ nanoscale reinforcing materials are only limitted to a small number of techniques, and can be with low cost production
The shape of complex geometry.Current melt processing method (the shear-mixed or ultrasound of such as metal matrix nanocomposite
Wave processing) due to reactivity and the dispersion and the finite availability by compatible material is influenced.These methods can disperse
Certain reinforced phases of low volume percentage;However, there is complication under higher enhancing volume percentage load, because of dispersion
Influence become to be more localized and effect is worse under higher melt viscosity.
The method of production high-volume fractional nanocomposite mixes nanoparticle dependent on various high cost methods at present
Son.High-energy ball milling can be used to mix in these, which is physically applied to nano material in host material, and
Then remaining material is processed into component.This needs batch processing.In addition, there are costs and safety for very big high energy ball mill
Both obstacles.Nano material can also mix in melt, but due to surface energy relevant to liquid metals, the distribution of nano material
It may be difficult.Ultrasonic wave mixing or high shear mixing may be effective, but they size-constrained and need to manipulate
Metal is melted, this brings cost and safety obstacle again.Another method utilizes semisolid, wherein being mixed by friction-stir process
Particle.This is high localized, and cannot scale immediately.
Functionally graded metal matrix matter nanocomposite is also wanted to, certain type of function is contained in nanocomposite
It can gradient (for example, nanoparticle concentration).Functionally graded metal matrix matter nanocomposite not yet uses Conventional melt processing method
Success produces, this is largely due to the high response of reinforced phase in metal bath.
The metal matrix nanocomposite that high-energy ultrasonic process for producing is evenly dispersed is used, to enhance nanoparticle
Dispersion and wetting characteristics in metal bath.The technology is added to molten dependent on the ex situ of cavitation and the acoustics driving of gas
The mixing of particle in body.Due in the particle unstability being completely dispersed in required very long processing, not yet in this way
Produce functionally graded material.It is steady that ultrasonication process is inherently limited in processing and process of setting the height in fusing matrix
Fixed particle.
In addition, the wetability of many potential reinforced phases makes them cannot be used for ex situ melt-processing techniques, wherein will
Particle mutually includes the wetability for being highly dependent on particle phase and metal matrix in the melt.Granulate-matrix compatibility requirements inhibit
The availability of acceptable reinforced phase in the production of metal matrix nanocomposite.In addition, being loaded in ultrasonic disperse technology big
Measuring nanoparticle becomes problem, because becoming under influence high melt viscosity caused by the reinforced phase loaded as high volume of dispersion
More limit to.
Friction stir process can generate gold by driving particle mutually to enter metal by the semisolid generated with probe friction
Belong to substrate nano composite material.Friction stir process has been used for production functionally graded metal matrix matter nanocomposite;However, should
Process is geometrically being restricted, and cannot be used together with the metal in no feasible semi-solid processing region with alloy.
Friction stir process can change the microstructure integrality of discrete material, because the amount of heat of the friction from generation influences
Surrounding's microstructure near processing district.In addition, the thickness of the component produced in friction stir process is limited in several inches.Friction
The fouling of stir process is very limited, and the production of a large amount of metal matrix nanocomposites is infeasible.
It is presently available for the high cost of nanocomposite, lack availability and lacks alloy diversity and demonstrates production
The difficulty of these materials.
Conventional melt-processing techniques (such as liquid agitation processing, Semi-solid Stirring processing and ultrasonic wave processing) can divide
Dissipate low volume with the nonreactive reinforced phase of metal bath.Desirably one kind can be realized high volume load and reactivity enhancing
The mutually method of the two.
A kind of method for producing functionally graded metal matrix matter nanocomposite is also sought to, this method is suitable for conventional melt
Body processing technology, wherein a variety of acceptable materials can be used.A kind of method is needed to receive to produce functionally graded metal matrix matter
Nano composite material, wherein process time is restricted, so that nanoparticle is non-degradable in process.
Summary of the invention
The present invention solves the above-mentioned needs in this field, such as now will be summarizing and then hereinafter further
It describes in detail.
Some modifications of the invention provide a kind of composition comprising metalliferous micro particles and nanoparticle, wherein receiving
Rice corpuscles is chemical and/or is physically located on the surface of micro particles, and wherein nanoparticle spreads composition with three-dimensional
Construction consolidation.
In some embodiments, the composition is the ingot for producing metal nanometer composite material.In other embodiments
In, the composition itself is metal nanometer composite material.
For example, micro particles can contain element selected from the group below, which is made up of: Al, Mg, Ni, Fe, Cu, Ti,
V, Si, and combinations thereof.For example, nanoparticle can contain compound selected from the group below, which is made up of: metal, ceramics,
Cermet, intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.In certain implementations
In example, micro particles contain Al, Si and Mg (for example, alloy AlSi10Mg), and nanoparticle contains tungsten carbide (WC).
In some embodiments, micro particles have the average micro particles size from about 1 micron to about 1 centimetre.One
In a little embodiments, average nanoparticle size that nanoparticle has from about 1 nanometer to about 1000 nanometer.
The composition can be containing from about 10wt% to the micro particles of about 99.9wt%.In these or other embodiments
In, the composition contains the nanoparticle from about 0.1wt% to about 10wt%.
Other modifications of the invention provide a kind of functionally graded metal matrix matter nanocomposite, and it includes metal-matrix
Phase and the first reinforced phase containing the first nanoparticle, wherein nanocomposite contains at least one by nanocomposite
The concentration gradient of first nanoparticle of a dimension.The concentration gradient of nanoparticle can be at least 100 microns of length scale
Inside it is present in nanocomposite.In some embodiments, nanocomposite has cast microstructure.
In some embodiments, nanocomposite is master alloy.Metal-matrix can mutually contain member selected from the group below
Element, the group are made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si, and combinations thereof.First nanoparticle, which can contain, to be selected from down
The compound of group, which is made up of: metal, ceramics, cermet, intermetallic alloy, oxide, carbide, nitride,
Boride, polymer, carbon, and combinations thereof.In some embodiments, metal-matrix mutually contains Al, Si and Mg, and first receives
Rice corpuscles contains tungsten carbide (WC).
The average grain diameter that first nanoparticle can have from about 1 nanometer to about 1000 nanometer.In some embodiments, one
A little or all first nanoparticles can be with agglomeration, so that the effective grain size in nanoparticle phase is greater than 1000 nanometers.
For example, nanocomposite can contain the metal-matrix phase from about 10wt% to about 99.9wt%.For example, receiving
Nano composite material can contain the first nanoparticle from about 0.1wt% to about 10wt%.
In some embodiments, nanocomposite further includes in the first reinforced phase and/or the second reinforced phase
Two nanoparticles.
In some embodiments, metal-matrix phase and the first reinforced phase respectively spread nanocomposite dispersion.At these
Or in other embodiments, metal-matrix phase and the first reinforced phase are arranged in nanocomposite with layered configuration, wherein this point
Layer configuration includes at least first layer comprising the first nanoparticle and at least second layer comprising metal-matrix phase.
Nanocomposite can reside in at least one 100 microns or larger size, such as 1 millimeter or larger size
Object in.
Certain modifications of the invention provide a kind of functionally graded metal matrix matter nanocomposite, it includes containing Al, Si,
Reinforced phase with the metal-matrix phase of Mg and containing W and C, wherein nanocomposite contains through nanocomposite extremely
The concentration gradient of the reinforced phase of a few dimension.Nanocomposite can have cast microstructure.
In certain embodiments, metal-matrix mutually contains aluminium alloy AlSi10Mg.In certain embodiments, reinforced phase contains
There is tungsten carbide (WC).In some embodiments, metal-matrix phase and reinforced phase are arranged with layered configuration in nanocomposite
Interior, wherein the layered configuration includes the first layer comprising W and C and Al, Si and Mg and the second layer comprising Al, Si and Mg.
Other modifications of the invention provide a kind of method for preparing metal nanometer composite material, this method comprises:
(a) precursor composition comprising metalliferous micro particles and nanoparticle is provided, wherein nanoparticle chemistry and/or object
Reason ground is arranged on the surface of micro particles;
(b) precursor composition is consolidated into the intermediate composition comprising metalliferous micro particles and nanoparticle, wherein receiving
Rice corpuscles is throughout intermediate composition with three-dimensional construction consolidation;And
(c) intermediate composition is processed to convert metal nanometer composite material for the intermediate composition.
In some embodiments, precursor composition is in powder type.In some embodiments, intermediate composition is in ingot shape
Formula.In some embodiments, final nanocomposite can have cast microstructure.
Micro particles can contain element selected from the group below, which be made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si,
And combinations thereof.Nanoparticle can contain compound selected from the group below, which be made up of: metal, ceramics, cermet,
Intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.
In various embodiments, step (b) include compacting, bonding, sintering, or combinations thereof.
In various embodiments, step (c) include compacting, sintering, mixing, dispersion, Friction Stir Welding, extrusion, bonding,
Fusing, semisolid fusing, capacitor discharge sintering, casting, or combinations thereof.
In some embodiments, metal phase and the first reinforced phase respectively spread nanocomposite dispersion.These or its
In his embodiment, metal phase and the first reinforced phase are arranged in nanocomposite with layered configuration, wherein the layered configuration packet
Include at least first layer comprising nanoparticle and at least second layer comprising metal phase.
Other modifications provide a kind of method for preparing functionally graded metal matrix matter nanocomposite, this method comprises:
(a) precursor composition (for example, powder) comprising metalliferous micro particles and nanoparticle is provided, wherein nanoparticle
Chemistry and/or be physically located on the surface of micro particles;
(b) precursor composition is consolidated into the intermediate composition comprising metalliferous micro particles and nanoparticle (for example, ingot
Material), wherein nanoparticle is throughout intermediate composition with three-dimensional construction consolidation;
(c) intermediate composition is melted to form melt, and wherein the melt separation is at first comprising metalliferous micro particles
Phase and the second phase comprising nanoparticle;And
(d) solidify the melt to obtain metal matrix nanocomposite, there is at least one for passing through nanocomposite
The concentration gradient of the nanoparticle of dimension.
Micro particles can contain element selected from the group below, which be made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si,
And combinations thereof.Nanoparticle can contain compound selected from the group below, which be made up of: metal, ceramics, cermet,
Intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.In some embodiments, micron
Particle contains Al, Si and Mg, and nanoparticle contains tungsten carbide (WC).
In various embodiments, step (b) include compacting, bonding, sintering, or combinations thereof.
In various embodiments, step (c) include compacting, sintering, mixing, dispersion, Friction Stir Welding, extrusion, bonding,
Fusing, semisolid fusing, capacitor discharge sintering, casting, or combinations thereof.Step (c) can also include effectively stopping melt holding
The time is stayed to cause the separation of the first phase with the density-driven of the second phase.For example, the residence time can be selected from about 1 minute to about 8
Hour.In some embodiments, step (c) include make melt be exposed to selected from gravity, centrifugation, machinery, electromagnetism, or combinations thereof
External force.
Step (d) may include the directional solidification of melt.In some embodiments, nanocomposite has casting microcosmic
Structure.Metal-matrix phase and the first reinforced phase can respectively disperse throughout nanocomposite.In these or other embodiments
In, metal-matrix phase and the first reinforced phase are arranged in nanocomposite with layered configuration, and wherein the layered configuration includes packet
At least first layer containing nanoparticle and at least second layer comprising metal-matrix phase.
The concentration gradient of nanoparticle can be present in nanocomposite at least 100 microns of length scale.
Other modifications of the invention provide a kind of method for preparing master alloy metal matrix nanocomposite, this method packet
It includes:
(a) the ingot composition comprising metalliferous micro particles and nanoparticle is provided, wherein nanoparticle chemistry and/or object
Reason ground is arranged on the surface of micro particles, and wherein nanoparticle spreads ingot composition with three-dimensional construction consolidation;
(b) the ingot composition is melted to form melt, and wherein the melt separation is at first comprising metalliferous micro particles
Phase and the second phase comprising nanoparticle;
(c) solidify the melt to obtain metal matrix nanocomposite, there is at least one for passing through nanocomposite
The concentration gradient of the nanoparticle of dimension;And
(d) it compared with the rest part of metal matrix nanocomposite, removes a part and contains low concentration nanoparticle
Thus metal matrix nanocomposite generates master alloy metal matrix nanocomposite.
Micro particles can contain element selected from the group below, which be made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si,
And combinations thereof.Nanoparticle can contain compound selected from the group below, which be made up of: metal, ceramics, cermet,
Intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.In certain embodiments, micron
Particle contains Al, Si and Mg, and nanoparticle contains tungsten carbide (WC).
Step (b) may further include compacting, sintering, mixing, dispersion, Friction Stir Welding, extrusion, bonding, capacitor
Discharge sintering, casting, or combinations thereof.Step (b) may include keeping effective stay time (for example, about 1 minute to 8 melt
Hour) to cause the separation of the first phase with the density-driven of the second phase.Optionally, step (b) may include being exposed to melt
Selected from gravity, centrifugation, machinery, electromagnetism, or combinations thereof external force.
Step (c) may include the directional solidification of melt.In some embodiments, the metal matrix nanometer in step (c)
Composite material is characterized in that cast microstructure.The concentration gradient of first nanoparticle can be at least 100 microns of length
It is present in metal matrix nanocomposite in scale.
In some embodiments, metal-matrix phase and the first reinforced phase respectively spread metal matrix nanocomposite point
It dissipates.In these or other embodiments, metal-matrix phase and the first reinforced phase are multiple in metal matrix nanometer with layered configuration setting
In condensation material, wherein the layered configuration includes at least first layer comprising nanoparticle and at least the comprising metal-matrix phase
Two layers.
Step (d) may include processing, ablation, reaction, dissolution, evaporation, selective melting, or combinations thereof.In certain realities
It applies in example, step (d) provides two different master alloy metal matrix nanocomposites.
In some embodiments of the invention, one or more final master alloy metal matrix nanocomposites can have
There is cast microstructure.
Detailed description of the invention
The schematic diagram of this paper indicates the functionalization pattern that can be realized in an embodiment of the present invention and microstructure.These
Figure should not be construed as being limited in any way.It is furthermore noted that illustration contained in these figures is not necessarily drawn to scale, and
And for the purpose for understanding these embodiments, various degrees of amplification is used.
Fig. 1 depicts some embodiments, wherein the functionalised powder containing the metal micro particle for being coated with nanoparticle
It is converted into ingot (or other materials), wherein nanoparticle is orientated with three-dimensional structure.
Fig. 2 depicts some embodiments, wherein the functionalised powder containing the metal micro particle for being coated with nanoparticle
It is converted into melt or ingot (or other materials), and then nanoparticle is reacted in the melt to be formed and contain nanoparticle
New distribution phase.
Fig. 3 depicts some embodiments, these embodiments start from containing being coated with chemical and/or physically different
The functionalised powder of the metal micro particle of two types nanoparticle, and then be converted into contain by functionalised powder and be distributed
The melt or ingot (or other materials) of nanoparticle in metal phase.
Fig. 4 depicts some embodiments, these embodiments start from containing being coated with chemical and/or physically different
The functionalised powder of the metal micro particle of two types nanoparticle, and then one of nanoparticle in metal phase
Reaction and another do not react.
Fig. 5 depicts some embodiments, these embodiments start from being distributed in metal matrix in advance (such as in ingot)
Nanoparticle, with density-driven mutually separation, wherein nanoparticle is subsequently cured towards surface migration, to obtain function
It can graded metal matrix nanocomposite.
Fig. 6 depicts some embodiments, these embodiments start from being distributed in metal matrix in advance (such as in ingot)
Nanoparticle, with density-driven mutually separation, wherein nanoparticle is subsequently cured far from surface migration, to obtain function
It can graded metal matrix nanocomposite.
Fig. 7 depicts some embodiments, these embodiments start from being distributed in metal matrix in advance (such as in ingot)
Total dispersing nanoparticles, with density-driven mutually separation, some of nanoparticles other nanometers far from surface migration
Particle is subsequently cured towards surface migration, to obtain functionally graded metal matrix matter nanocomposite.
Fig. 8 depicts some embodiments, these embodiments start from being distributed in metal matrix in advance (such as in ingot)
Total dispersing nanoparticles, with density-driven mutually separation, wherein nanoparticle is subsequently cured far from surface migration, thus
Obtain functionally graded metal matrix matter nanocomposite.
Fig. 9 depicts some embodiments, these embodiments start from being distributed in metal matrix in advance (such as in ingot)
Total dispersing nanoparticles, with density-driven mutually separation, wherein nanoparticle is subsequently cured towards surface migration, thus
Obtain functionally graded metal matrix matter nanocomposite.
Figure 10 is the exemplary AlSi10Mg-WC functionally graded metal matrix matter nanocomposite according to present example 1
The SEM image of cross section (side view).
Figure 11 is the cross according to the exemplary AlSi10Mg-WC master alloy metal matrix nanocomposite of present example 2
The SEM image in section (side view).
Figure 12, which is depicted, contains phase by generating functionally graded metal matrix matter nanocomposite first and then removing
The master alloy metal matrix that nanoparticle is rich in metal matrix is mutually generated to the material of the nanoparticle of low volume fraction
Some embodiments of nanocomposite.
Figure 13, which is depicted, contains phase by generating functionally graded metal matrix matter nanocomposite first and then removing
The master alloy metal matrix that nanoparticle is rich in metal matrix is mutually generated to the material of the nanoparticle of low volume fraction
Some embodiments of nanocomposite.
Figure 14, which is depicted, contains phase by generating functionally graded metal matrix matter nanocomposite first and then removing
Two types nanoparticle is mutually rich in metal matrix to generate to the material of the two types nanoparticle of low volume fraction
Master alloy metal matrix nanocomposite some embodiments.
Figure 15, which is depicted, contains phase by generating functionally graded metal matrix matter nanocomposite first and then removing
Different type nanoparticle is mutually rich in metal matrix to generate to the material of the two types nanoparticle of low volume fraction
Two kinds of different master alloy metal matrix nanocomposites some embodiments.
Specific embodiment
Composition of the invention, structure, system and method will be carried out detailed by reference to various non-limiting embodiments
Explanation.
This explanation will enable those skilled in the art manufacture and use the present invention, and this specification describes this hairs
Bright several embodiments, modification, modification, alternative solution and purposes.In conjunction with attached drawing with reference to of the invention described in detail below
When, these and other embodiments, feature and advantage of the invention will become brighter for a person skilled in the art
It is aobvious.
As used in this specification and the appended claims, unless the context clearly, otherwise singular shape
Formula " one/one (a/an) " and " described " include plural reference.Unless otherwise defined, otherwise all technologies used herein and
Scientific term all has the identical meaning that those skilled in the art are generally understood.
Unless otherwise instructed, the institute of the expression condition, concentration, the size that otherwise use in the specification and claims etc.
There is numerical value to should be understood to be modified by term " about " in all cases.Therefore, unless the contrary indication, otherwise in following theory
The numerical parameter illustrated in bright book and the appended claims is approximation, these approximations can be according at least to specific analysis
Technology and change.
Synonymous term " includes with " including (including) ", " containing (containing) " or " being characterized in that "
It (comprising) " is inclusiveness or open and be not excluded for other, unlisted element or method and step." packet
Containing " it is technical term used in claim language, mean that specified claim elements are necessary, but can add
Add other claim elements and still constitutes concept within the scope of the claims.
As used herein, phrase " by ... form " do not include any element that do not specify in detail in the claims, step,
Or ingredient.When phrase " by ... form " (or its modification) appear in claim main body clause in, rather than immediately preceding
When after speech, which only limits the element illustrated in the clause;Other element be not excluded as a whole claim it
Outside.As used herein, the scope of the claims is limited to specified element or method and step by phrase " mainly by ... form ",
In addition not substantially affecting those of basis and one or more novel feature of theme claimed.
About term "comprising", " by ... form " and " substantially by ... form ", when using these three arts herein
Language for the moment, discloses at present and claimed theme may include using any of other two terms.Therefore, exist
In some embodiments not in addition being expressly recited, any example of "comprising" can be substituted for " by ... form " or it is alternative
Ground is substituted for " mainly by ... form ".
Variant of the invention is based on the cured control of dusty material.Control solidification can have huge shadow to microstructure
It rings, and therefore there is tremendous influence to material property (for example, intensity and toughness).In some cases, solidification faster
It is desirable;And in other cases, slowly solidification can produce desired microstructure.In some cases, it does not wish
Prestige allows powder to be completely melt;But it only melts and solidifies on powder surface.Present invention offer controls material over time and space
Expect cured approach, which utilizes the surface functionalization of the raw powder of processing.
Some modifications, which are provided, solidifies the approach controlled to the material that is generally difficult to process or can not be capable of processing.Herein
The principle of disclosure can be applied in increasing material manufacturing and the interconnection technique as welded.Certain nonweldable metals are (such as high-strength
Spend aluminium alloy (such as aluminium alloy 7075,7050 or 2199)) the good candidates metal of increasing material manufacturing will be become, but it is frequently subjected to heat
The puzzlement split.The methods disclosed herein, which allows to split in the case that tendentiousness significantly reduces, processes these alloys.
Properly control solidification can produce biggish part reliability and improve yield.Some embodiments of the present invention mention
For the component with the comparable powder metallurgy processing of mechanism part.Some embodiments provide formed during component manufacture rather than
The corrosion-resistant surface coating formed with additional step.
This disclosure describes independently of heat input or comes in conjunction with heat input the nucleation and life inside control structure
Long dynamics.This disclosure, which describes, to be mutually incorporated to structure control to generate the method that three-dimensional microstructures construct.It provides
Removing content/pollutant and the method for forming composite construction.
Variant of the invention is based on control solidification in the following manner: with environmental restrictions or increase thermal conductivity and/or radiation,
The heat load during solidifying is controlled using the enthalpy of formation and change thermal capacitance, and/or utilizes the final cured article of surface tension transition
Undesirable substance is repelled in the middle retention for wishing substance.
Some modifications provide the method for control nanoparticle (or micro particles)/material separation.Rapid solidification techniques are answered
When using in powder processing, unique microstructure can be formed.Equally, before melting nanoparticle or micro particles in grain
Configuration around sub can introduce three-dimensional manometer particle configuration throughout microstructure.
The embodiment of the present invention provides three-dimensional manometer particle configuration in metal microstructure.It is not intended to by theoretical pact
Beam, these constructions can significantly improve material property by the dislocation motion on obstruction, prevention or redirection specific direction.It should
It was found that can be used for controlling inefficacy mechanism getting well than existing isotropism or anisotropic material.
The present invention is not limited to metal materials, and can be mentioned with significantly lighter, more repeatable and energy-efficient production method
For similar benefit.The semi-passive property of the technique is typically not necessarily to change existing tool, and can be used for existing manufacture
In setting.
The production of metal matrix nanocomposite
Some modifications of the invention provide the starting material or material bodies that can be used for producing metal matrix nanocomposite
System, and the metal matrix nanocomposite obtained by it." metal matrix nanocomposite " (or " MMNC ") or equivalent
Ground " metal nanometer composite material " is metalliferous material, and there is the nanoparticle greater than 0.1wt% to be distributed in metal matrix
In or otherwise in metalliferous material.
Nanocomposite has been found to show the mechanical strength of enhancing due to that can prevent dislocation motion.This energy
Power is not limited to room temperature, and the elevated temperature strength and creep resistance of material can be improved.Nanocomposite can also be in certain cunnings
Improve wearability and pollution resistance in dynamic and high friction environment.However, therefore nanocomposite so far is difficult to produce and
Their use is restricted.
Variant of the invention is to find to produce any metal matrix nanocomposite formed and control nanoparticle daughter
Premised on the approach of fraction.It is (entitled " for producing Metal Substrate from the functionalization raw metal described in the description below
The functionalization raw metal of matter nanocomposite " part) start, low or high-volume fractional nanoparticle may be implemented.It is logical
It crosses and is processed using conventional inexpensive powder metallurgy process and ingot, there may be nanoparticles uniform or heterogeneous in the substrate
Son distribution.
" functionalization metal " or " functionalization raw metal " includes metal micro particle, wherein being assembled with one kind on the surface
Or a variety of different nanoparticles.Nanoparticle is typically the composition different from basic micropowder.
Nanoparticle is chemical and/or is physically located on the surface of micro particles.That is, electrostatic can be used
Power, Van der Waals force, chemical bond, mechanical bond, and/or any other one or more power adhere to nanoparticle.Chemical bond is
Atom is held together in the power in molecule or compound.Electrostatic force and Van der Waals force are the realities that can cause the physical force combined
Example.Mechanical bond is the combination generated when molecular entity is wound in space.Typically, chemical bond is more stronger than physical bond.
Interested nanoparticle includes carbide, nitride, boride, oxide, intermetallic compound or is processing
When can form one of above-mentioned material or a variety of other materials.Size, shape and the composition of nanoparticle can be extensive
Variation.Nanoparticle typically has the average nanoparticle of from about 1 nanometer to about 1000 nanometer (such as from about 250 nanometers or smaller)
Size.In some embodiments, lesser nanoparticle is conducive to increase intensity.In some applications, biggish group can be used
Gradation (such as from about 250-1000 nanometers or bigger) handles the material to generate desired material.
Some modifications provide it is a kind of production for produce metal nanometer composite material extensive raw material it is cost-effective
Approach.Some embodiments utilize the function as described in the U.S. Patent Application No. 15/209,903 submitted on July 14th, 2016
Change powder raw material, which is incorporated herein by reference hereby.This disclosure is not limited to these functionalised powders.
Some modifications of the invention provide a kind of metal matrix nanometer comprising metalliferous micro particles and nanoparticle
Composite, wherein nanoparticle is chemical and/or is physically located on the surface of micro particles, and wherein nanometer
Particle is throughout composition with three-dimensional construction consolidation.
It is to be distributed at random throughout metal matrix nanocomposite that " three-dimensional construction ", which means nanoparticle not,.On the contrary, receiving
In the three-dimensional construction of rice corpuscles, at the interval in space (three-dimensional) between nanoparticle, there are certain laws.Nanoparticle it
Between average headway can change, such as from about 1 diameter of nano particles to about 100 diameter of nano particles or more, this depends on material
Nanoparticle concentration in material.
In some embodiments, in metal matrix nanocomposite nanoparticle three-dimensional construction and starting composition
The distribution phase of nanoparticle in (functional micro particles, i.e., on the surface with the metalliferous micro particles of nanoparticle)
It closes.It is as shown in Figure 1 to this explanation.When the dynamics in control fusing and process of setting makes the integrality for keeping nanoparticle
When with dispersibility, this three-dimensional construction of nanoparticle is possible.
In some embodiments, nanoparticle metal matrix fusing after and it is then non-fusible during solidification and
Do not disperse significantly from original configuration relative to each other.In certain embodiments, nanoparticle metal matrix fusing after and/or
It melted during solidification, soften (such as becoming glass) or form liquid-Solutions Solution, but is not aobvious from original configuration relative to each other
Write dispersion.When solidification (or the experience phase transformation) again during melt solidification of such nanoparticle, its original configuration is presented in they
Or its approximate coordinate.In some embodiments, no matter whether nanoparticle melts, and nanoparticle is finally in three-dimensional construction
In, wherein the position of nanoparticle is different from original configuration, but can be related and therefore predictable based on starting functionalization raw material.
In some embodiments, the composition is the ingot for producing metal matrix nanocomposite.In other realities
It applies in example, the composition itself is metal matrix nanocomposite.
For example, micro particles can contain element selected from the group below, which is made up of: Al, Mg, Ni, Fe, Cu, Ti,
V, Si, and combinations thereof.For example, nanoparticle can contain compound selected from the group below, which is made up of: metal, ceramics,
Cermet, intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.In certain implementations
In example, micro particles contain Al, Si and Mg (for example, alloy AlSi10Mg), and nanoparticle contains tungsten carbide (WC).
Some modifications of the invention provide a kind of method for preparing metal matrix nanocomposite, this method comprises:
(a) precursor composition comprising metalliferous micro particles and nanoparticle is provided, wherein nanoparticle chemistry and/or object
Reason ground is arranged on the surface of micro particles;
(b) precursor composition is consolidated into the intermediate composition comprising metalliferous micro particles and nanoparticle, wherein receiving
Rice corpuscles is throughout intermediate composition with three-dimensional construction consolidation;And
(c) intermediate composition is processed to convert metal matrix nanocomposite for the intermediate composition.
In some embodiments, precursor composition is in powder type.In some embodiments, intermediate composition is in ingot shape
Formula.
Micro particles can contain element selected from the group below, which be made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si,
And combinations thereof.Nanoparticle can contain compound selected from the group below, which be made up of: metal, ceramics, cermet,
Intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.Typically, it micro particles and receives
The composition of rice corpuscles is different, although chemical composition can be the same or similar, while physical characteristic (partial size, equal) is deposited
In difference.
The composition can be containing from about 10wt% to the micro particles of about 99.9wt%.In these or other embodiments
In, the composition contains the nanoparticle from about 0.1wt% to about 10wt%.The nanoparticle of higher concentration is possible, spy
It is not when physics removes the region with low concentration (such as discussed further below).When tenor is low (such as 20wt% or less)
When, metal matrix nanocomposite can be accredited as " cermet ".
In some embodiments, at least 1% surface area of micro particles contains chemistry and/or is physically located in micron
Nanoparticle on particle surface.When wishing higher nanoparticle concentration in final material, preferably micro particles are more
High surface area contains nanoparticle.In various embodiments, micro particles at least 1%, 2%, 5%, 10%, 20%, 30%,
40%, 50%, 60%, 70%, 80%, 90% or 95% total surface area contains chemistry and/or is physically located in micron grain
Nanoparticle on sublist face.
In some embodiments, micro particles have the average micro particles size from about 1 micron to about 1 centimetre.Each
In kind embodiment, average micro particles size is about 5 microns, 10 microns, 50 microns, 100 microns, 200 microns, 500 microns, 1
Millimeter, 5 millimeters or 10 millimeters.
In some embodiments, nanoparticle has the average nanoparticle size from about 1 nanometer to about 1000 nanometer.?
In various embodiments, average nanoparticle size is about 2,5,10,25,50,100,200,300,400,500,600,700,
800 or 900 nanometers.
In some embodiments, metal matrix has from about 2g/cm3To about 10g/cm3Density.In some embodiments,
Nanoparticle independently has from about 1g/cm3To about 20g/cm3Density.
" consolidation " and " consolidation " refers to that precursor composition (for example, raw material powder) is converted into comprising metalliferous micron grain
The intermediate composition of son and nanoparticle.In various embodiments, the consolidation in step (b) include compacting, bonding, sintering or
A combination thereof.Alternatively or additionally, consolidation may include it is metal injection molded, squeeze out, etc. static pressure, power forging, be injected into
Shape, metal increasing material manufacturing, and/or other known technologies.Green compact are properly termed as by the intermediate composition that step (b) generates.
In various embodiments, the processing in step (c) includes compacting, sintering, mixing, dispersion, Friction Stir Welding, squeezes
Out, bond and (such as use polymer adhesive), fusing, semisolid fusing, be sintered, cast, or combinations thereof.Fusing may include induction
Fusing, resistance melting, skull fusing, arc-melting, laser fusing, electron-beam melting, semisolid fusing or other kinds of molten
Change (including conventional and unconventional melt-processing techniques).Casting may include such as centrifugation, casting or gravitational casting.Sintering can
To include such as spark discharge, capacitor electric discharge, resistance or furnace sintering.Mixing may include such as convection current, diffusion, shear-mixed,
Or ultrasonic mixing.
Precursor composition (for example, functionalised powder) cotransformation is green compact or finished product body by step (b) and (c), then
It can be used for other post-processing, be machined into component or other purposes.
In some embodiments, metal-matrix phase and the first reinforced phase respectively spread nanocomposite dispersion.At these
Or in other embodiments, metal-matrix phase and the first reinforced phase are arranged in nanocomposite with layered configuration, wherein this point
Layer configuration includes at least first layer comprising nanoparticle and at least second layer comprising metal-matrix phase.
In some embodiments, final metal matrix nanocomposite can have cast microstructure." casting is microcosmic
Structure " means that metal matrix nanocomposite is characterized in that multiple dendrite and crystal boundary in microstructure.In some implementations
In example, there is also multiple gaps, but are preferably without crack or big phase boundary.Dendrite is the characteristic tree of crystal,
Generation is quickly grown along crystallization direction advantageous on energy by crystal when melting metal and freezing.
Although note that casting be metalworking technology, cast microstructure is structure feature, not necessarily with prepare it is microcosmic
Any special process of structure is related.Cast microstructure can of course be produced by the freezing (solidification) of fusing metal or metal alloy
It is raw.However, metal freezing may cause other microstructures, and cast microstructure can be produced by other metal-forming techniques
It is raw.The smithcraft (for example, forming technology) for being completely independent of fusing and solidification would tend to not generate cast microstructure.
Cast microstructure usually can be for example, by primary dendrite spacing, secondary dendrite spacing, dendroid Chemical Decomposition
Distribution, crystallite dimension, shrinkage porosity rate (if any), the percentage of the second phase, the composition of the second phase and dendroid/etc.
Axis changes to characterize.
In some embodiments of the invention, cast microstructure is further characterized by the microcosmic knot of equiaxial fine grain
Structure." isometric " crystal grain means that length, width and the height of crystal grain are roughly equal.When in the presence of by being included in micro particles surface
What multiple nanoparticles upper, in functionalization raw metal simultaneously therefore in final metal matrix nanocomposite generated is permitted
When more nucleation sites, equi-axed crystal can produce.
In some embodiments of the invention, the microstructure for being further characterized by dispersion of cast microstructure.Point
Scattered microstructure usually by microstructure a large amount of dendrite and crystal boundary generate, again by micro particles surface largely receiving
Rice corpuscles generates.Degree of scatter can be characterized by breakup length scale, which is calculated as nanoparticle
Between average headway and/or nanoparticle between metal phase in average length scale.In various embodiments, dispersion length
Scale degree is from about 1 nanometer to about 100 micron, such as from about 10 nanometers to about 10 micron, or about 100 nanometers to about 1 micron.
It is optionally possible to which porosity is removed or reduced in cast microstructure.For example, can carry out reheating and/
Or pressurization (or other mechanical forces) handles so that porous gap present in metal matrix nanocomposite minimizes.In addition,
It can be by physically removing (for example, excision) separated region in porous gap (the mutually separation as passed through density-driven) from gold
Belong in substrate nano composite material and removes hole.About the example, referring to Figure 10 and Figure 11, wherein removing in the microstructure of Figure 10
Existing gap is to reach the microstructure of the dispersion of Figure 11.Breakup length scale in Figure 11 is about 1-5 microns.
Other than removing gap, other post-processings can be carried out, it is possible to create be not cast microstructure, or contain
Other final microstructures of microstructure mixture.For example, forging can improve the defect of ingot casting or continuous rod casting, and such as
Fruit wishes that other direction intensity can be introduced.Preprocessing (for example, strain hardening) can be carried out, is needing maximum strong to generate
The grain flow that the side of degree is upwardly oriented.Therefore, in certain embodiments, final microstructure can be forging microstructure, or
Mix casting/forging microstructure.In various embodiments, it is based on volume, metal matrix microstructure is at least 10%,
25%, 50%, 75%, 90%, 95%, 99% or 100% cast microstructure.
It is worth noting that, friction stir process needs rapid quenching to avoid heavy by what is occurred during slow solidification
Drop and agglomeration.Rapid quenching tend to produce be not cast microstructure as herein defined microstructure.Additionally, it is contemplated that
It is the microstructure for dispersing cast microstructure that Bridgeman type consolidation, which will be presented not,.
Some modifications of the invention provide a kind of raw material that the consolidation method by functionalised powder produces, can be with production
It is used to prepare nanocomposite or is the ingot of nanocomposite in itself.As described in elsewhere, metal alloy and nanometer
Particle composition can be widely varied.The metal matrix nanocomposite of this paper can be inclined by composition bias assembly, density
Component, classification dimensions component or other kinds of nanoparticle component is pressed to manufacture.Nanoparticle can be protected in ingot formation
Identical composition is held, nanoparticle can be reacted in some way to form the more favorable material for being used for nanocomposite,
A variety of different nanoparticles can be used, or this any combination can occur.
Some graphical representations are shown in Fig. 1 to 4, these figures are the exemplary implementation of metal matrix nanocomposite
Example.
Fig. 1 depicts some embodiments, wherein the function containing the metal micro particle 105 for being coated with nanoparticle 110
Change powder such as passes through application heat and pressure is consolidated into ingot (or other materials), which contains is distributed throughout metal phase 115
Nanoparticle 120.Ingot 115/120 keeps the three-dimensional construction for the nanoparticle 120 being uniformly distributed throughout metal matrix 115.
As shown in the amplifier section of ingot (right-hand side of Fig. 1), nanoparticle 120 is taken in metal matrix 115 with three-dimensional structure
To.In some embodiments, based on the starting material (function i.e. containing the metal micro particle 105 for being coated with nanoparticle 110
Change powder), the three-dimensional structure can be predicted.That is, the size and each micron of grain of micro particles 105 and nanoparticle 110
Interval between son 105 and between each nanoparticle 110 can be with each nanoparticle in ingot in metal phase 115
Interval (three-dimensional) between 110 is related.
Fig. 2 depicts some embodiments, wherein the function containing the metal micro particle 205 for being coated with nanoparticle 210
Change powder and is converted into melt or ingot (or other materials) containing the nanoparticle 210 being distributed throughout metal phase 215.Then
Nanoparticle 210 is reacted in the melt to form the new distribution phase 225 containing nanoparticle 220.Initial nanoparticle 210 passes through
It experienced chemical transformation with reacting for metal phase 215, to form nanoparticle 220.
Fig. 3 depicts some embodiments, these embodiments start from containing being coated with chemical and/or physically different
The functionalised powder of the metal micro particle 305 of nanoparticle 310 and 320.Apply heat and by functionalised powder be converted into containing
It is distributed in the melt or ingot (or other materials) of the nanoparticle 310 and 320 in metal phase 315.Nanoparticle 310 and 320
Concentration can be it is uniform or non-uniform.
Fig. 4 depicts some embodiments, these embodiments start from containing being coated with chemical and/or physically different
The functionalised powder of the metal micro particle 405 of nanoparticle 410 and 420.Apply heat and by functionalised powder be converted into containing
It is distributed in the ingot (or other materials) of the nanoparticle 410 and 420 in metal phase 415.Then apply heat and/or pressure and
Nanoparticle 420 is reacted to nanoparticle 440 in cenotype, and nanoparticle 410 does not react and as nanoparticle 410
It is distributed in metal phase 425.
Fig. 4 also show reinforced phase can by the in-situ chemical reaction with matrix components rather than (or in addition to) ex situ
Method generates.In ex situ method, reinforcing material is synthesized in outside, and is then added to base during composite material manufacture
In matter.
Functionally graded metal matrix matter nanocomposite
In some variations, the present invention provides a kind of functionally graded metal matrix matter nanocomposite and its manufacturing method.
As contemplated herein, " functionally graded metal matrix matter nanocomposite " is metal matrix nanocomposite, shows source
From the spatial gradient of one or more characteristics of some spatial variations in nanoparticle or the metal matrix of nanoparticle phase.Become
The characteristic of change can be the functional characteristic of machinery, heat, electricity, photon, magnetism or any other type.Some modifications provide one kind
The functionally graded metal matrix matter nanocomposite that density-driven separation (concentration or consumption) by enhancing particle generates.
Metal-matrix composite is typically with the enhancing particle system for the micron-scale being evenly dispersed in metal matrix
It makes.In order to realize a greater amount of reinforcings, nanoscale preferably is reduced in size to by enhance particle.However, reinforced phase is reactive
The manufacturing machine meeting of metal matrix nanocomposite is mutually limited firmly with that cannot be completely dispersed in melt processing with nanoscale.
Functionally graded metal matrix matter nanocomposite is routinely even more difficult to, and is limited at friction-stir
Reason, this is geometrically being limited on composition.Use the raw metal with nanoparticle functionalization as mitigate melt processing in
Reactivity and the dispersion means, the functionally graded metal with geometry complicated shape and wide spectrum composition can be produced
Substrate nano composite material.It can be using known melt-processing techniques (such as centrifugal casting, gravitational casting or electromagnetism separation casting
Make) manufacture functionally graded metal matrix matter nanocomposite.
It has traditionally been proved the melt-processed of metal matrix nanocomposite to be difficult, partially due to fusing base
Particle unstability in matter and due to surface can and nanoparticle cannot be completely dispersed.On the contrary, in some implementations of the invention
In example, by reducing the reaction time in liquid using pre-dispersed metal matrix nanocomposite raw material powder, wherein
Nanoparticle is throughout raw material powder with three-dimensional construction consolidation.
Then can carry out density-driven mutually separate be optionally sequestered include metal matrix the first phase and comprising
Second phase of nanoparticle.The separation of nanoparticle and metal matrix is useful, because then nanoparticle selectively wraps
It is contained in solid reinforced phase, which has the characteristic of enhancing compared with metal matrix.The mutually separation of density-driven
It can lead to the higher concentration or lower concentration (that is, exhausting) of the nanoparticle in any specific phase.First phase can be liquid
Form or liquid-solid solution, and nanoparticle typically keeps solid or at least as the different materials phase in melt.Then
Melt is solidificated in the Graded Density that nanoparticle is generated in solid metal matrix nanocomposite.
Density Separation nanoparticle, such as centrifugation, gravity, heat, electricity, sound or other power can be passed through using various power.It is logical
The separation of density-driven can be accelerated by crossing application external force.It is worth noting that, the mutually separation of density-driven can rub with incompatible
The metal for wiping stir process is used together.
Nanoparticle concentration can change to 1.0, such as from about 0.05 from 0 in the volume fraction of entire material, 0.1,0.2,
0.3,0.4,0.5,0.6,0.7,0.8,0.9 or 0.95.Local nanoparticle concentration (volume fraction) will depend on nanoparticle
Initial amount (on micro particles surface), metal matrix characteristic and used isolation technics.After releasing, it is rich in
The region of nanoparticle can have up to 1.0 volume fraction, i.e., there is only nanoparticles in the phase.Similarly, it exhausts and receives
The region of rice corpuscles can have 0 volume fraction, i.e., does not have nanoparticle in the phase.It is low between high nanoparticle concentration
Transformation can be gradually gradient (for example, Fig. 5) or sharply gradient (for example, Figure 12).
Other than concentration gradient, there may also be the gradients of such as partial size and material phase.When point using density-driven
From when, density gradient also will be present certainly.Difference between nano-particles density and metal matrix density can be for example, at least
0.1,0.5,1,2,5,10 or 15g/cm3.Difference in example 1 is about 13g/cm3。
When using the separation of density-driven, density variation is depended on, the various length scales of gradient are possible.Example
Such as, when density variation is very big, nanoparticle can form high concentration in a region of material or layer.For example, the ladder
Degree can exist from about 10 microns to about 1 centimetre or in longer length scale.In a preferred embodiment, the long scale of gradient
Degree is at least 100 microns.
Nanocomposite is often very firm but there may come a time when lacking toughness, this may be to have under high nanometer particle load
Problem.It is classified by binding function, material property (such as toughness) can be kept, while the surface characteristic of enhancing, enhancing being provided
Overall permanence or enhancing overall characteristic.For example, compared with the metal-matrix composite enhanced with micron reinforcing material,
Functionally graded metal matrix matter nanocomposite can be designed to have the high rigidity surface for improving wear characteristic.Due in table
There is the nanoparticle of higher concentration, therefore improved wear characteristic is derived from the enhancing introduced with nanoscale at face or near it
Strengthening mechanism.
In some embodiments, ingot is prepared or obtains, for then producing metal matrix nanocomposite." ingot "
Or equally " pre-dispersed ingot " means the raw material containing both metal component and pre-dispersed enhancing nanoparticle component.?
After handling functionalised powder, or after handling metal matrix nanocomposite, ingot can be obtained.In some embodiments
In, ingot is containing the functionally gradient of nano-particles density.In some embodiments, ingot has or contains microstructure, should
Microstructure indicates the material by forming with the functionalized powder precursor of nanoparticle surface.This will lead to the nanometer in ingot
The 3D network of particle.
Ingot can be green compact or finished product base.Ingot relative density can be in the range of 10% to 100%, for example, meter
It calculates as the percentage of the theoretical density (tight) of contained component in ingot.
The use of ingot can change.It is further processed the redistribution that nanoparticle can be caused to spread structure.It can be with
Ingot is handled in this way, so that it is with following particular advantages: containing the objective body integral determined during functionalization
Several nanoparticle and has and be uniformly distributed due to the discrete nanoparticle component on metalliferous micro particles surface.
Some modifications of the invention provide a kind of functionally graded metal matrix matter nanocomposite, and it includes metal-matrix
Phase and the first reinforced phase containing the first nanoparticle, wherein nanocomposite contains at least one by nanocomposite
The concentration gradient of first nanoparticle of a dimension.The concentration gradient of nanoparticle can be at least 100 microns of length scale
Inside it is present in nanocomposite.In some embodiments, nanocomposite has cast microstructure.
Metal-matrix can mutually contain element selected from the group below, which be made up of: Al, Mg, Ni, Fe, Cu, Ti, V,
Si, and combinations thereof.First nanoparticle can contain compound selected from the group below, which is made up of: metal, ceramics, gold
Belong to ceramics, intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.In some embodiments
In, metal-matrix mutually contains Al, Si and Mg, and the first nanoparticle contains tungsten carbide (WC).
The average grain diameter that first nanoparticle can have from about 1 nanometer to about 1000 nanometer, such as from about 10,50,100,
200,300,400,500,600,700,800 or 900 nanometers.In some embodiments, some or all of first nanoparticles can
With agglomeration, so that the effective grain size in nanoparticle phase is greater than 1000 nanometers.
For example, nanocomposite can be containing the metal-matrix phase from about 10wt% to about 99.9wt% (such as from about
20wt%, 30wt%, 40wt%, 50wt%, 60wt%, 70wt%, 80wt% or 90wt%).
For example, nanocomposite can be containing the first nanoparticle from about 0.1wt% to about 50wt% (such as from about
1wt%, 5wt%, 10wt%, 20wt%, 30wt% or 40wt%).
In some embodiments, nanocomposite further includes in the first reinforced phase and/or the second reinforced phase
Two nanoparticles.
In some embodiments, metal-matrix phase and the first reinforced phase respectively spread nanocomposite dispersion.At these
Or in other embodiments, metal-matrix phase and the first reinforced phase are arranged in nanocomposite with layered configuration, wherein this point
Layer configuration includes at least first layer comprising the first nanoparticle and at least second layer comprising metal-matrix phase.
Nanocomposite can reside in at least one 100 microns or larger size, and such as 200 microns, 500 micro-
In rice, 1 millimeter, 5 millimeters, 1 centimetre or larger sized object or article.The size of object or article is widely varied.
Certain modifications of the invention provide a kind of functionally graded metal matrix matter nanocomposite, it includes containing Al, Si,
Reinforced phase with the metal-matrix phase of Mg and containing W and C, wherein nanocomposite contains through nanocomposite extremely
The concentration gradient of the reinforced phase of a few dimension.Nanocomposite can have cast microstructure.
In certain embodiments, metal-matrix mutually contains aluminium alloy AlSi10Mg.AlSi10Mg is a kind of typical casting
Alloy has good casting characteristics and is frequently used for the casting with thin-walled and complex geometric shapes.Its offer is good
Intensity, hardness and dynamic characteristic, and therefore can also be used in the component for being subjected to high load.It is to AlSi10Mg addition reinforced phase
Characteristic provides other benefit.In certain embodiments, reinforced phase contains tungsten carbide (WC).
In some embodiments, metal-matrix phase and reinforced phase are arranged in nanocomposite with layered configuration, wherein
The layered configuration includes the first layer comprising W, C, Al, Si and Mg and the second layer comprising Al, Si and Mg --- that is,
First layer is rich in W and C, such as in the form of WC nanoparticle.
In some embodiments, nanocomposite is master alloy, as discussed further below.
Other modifications provide a kind of method for preparing functionally graded metal matrix matter nanocomposite, this method comprises:
(a) precursor composition (for example, powder) comprising metalliferous micro particles and nanoparticle is provided, wherein nanoparticle
Chemistry and/or be physically located on the surface of micro particles;
(b) precursor composition is consolidated into the intermediate composition comprising metalliferous micro particles and nanoparticle (for example, ingot
Material), wherein nanoparticle is throughout intermediate composition with three-dimensional construction consolidation;
(c) intermediate composition is melted to form melt, and wherein the melt separation is at first comprising metalliferous micro particles
Mutually and include nanoparticle it is sub or slave its obtain the second phase;And
(d) solidify the melt to obtain metal matrix nanocomposite, there is at least one for passing through nanocomposite
The concentration gradient of the nanoparticle of dimension.
Micro particles can contain element selected from the group below, which be made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si,
And combinations thereof.Nanoparticle can contain compound selected from the group below, which be made up of: metal, ceramics, cermet,
Intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.In some embodiments, micron
Particle contains Al, Si and Mg, and nanoparticle contains tungsten carbide (WC).
In various embodiments, step (b) include compacting, bonding, sintering, or combinations thereof.
In various embodiments, step (c) include compacting, sintering, mixing, dispersion, Friction Stir Welding, extrusion, bonding,
Fusing, semisolid fusing, capacitor discharge sintering, casting, or combinations thereof.Step (c) can also include effectively stopping melt holding
The time is stayed to cause the separation of the first phase with the density-driven of the second phase.For example, the residence time can be selected from about 1 minute to about 8
Hour.In some embodiments, step (c) include make melt be exposed to selected from gravity, centrifugation, machinery, electromagnetism, or combinations thereof
External force.
Step (d) may include the directional solidification or consecutive solidification of melt.Directional solidification and consecutive solidification are in casting
Solidify type.Directional solidification is to occur from the distalmost end of casting, and advance and be introduced into mold towards wherein fluent material
The solidification in channel.Consecutive solidification is the solidification vertically advanced since the wall of casting and from the surface.
Metal-matrix phase and reinforced phase can respectively disperse throughout nanocomposite.In these or other embodiments,
Metal-matrix phase and reinforced phase are arranged in nanocomposite with layered configuration, and wherein the layered configuration includes comprising nanometer
At least first layer of particle and at least second layer comprising metal-matrix phase.Nanoparticle can undergo same amount of agglomeration.It receives
Agglomeration between rice corpuscles can cause nanoparticle to be combined together in chemistry or physically.Single nanoparticle can be
Existence or non-existence or detectable in reinforced phase, and length scale relevant to nanoparticle can become larger than 1000nm.
For example, the concentration gradient of nanoparticle can (such as at least 100 microns, length be of about 1 centimetre or more at least 10 microns
It is more) length scale in be present in nanocomposite.
In some embodiments, functionally graded metal matrix matter nanocomposite has the microcosmic knot of casting defined above
Structure.In certain embodiments, microstructure itself is there are functionally gradient, related with concentration gradient or independently of concentration gradient.
Fig. 5 to 10 shows the various embodiments of functionally graded metal matrix matter nanocomposite.
Fig. 5 depicts some embodiments, these embodiments start from being distributed in metal matrix 505 in advance (such as in ingot)
In nanoparticle 510.It can be obtained by heating the functionalised powder containing the metal micro particle for being coated with nanoparticle
Ingot, as shown in Figs 1-4.Ingot is applied heat to, which undergoes the mutually separation of density-driven, wherein melting since density is less than
Change the density of matrix 515, nanoparticle 510 is migrated towards surface (resisting gravity).After solidification, gained functionally graded metal
Substrate nano composite material contains the nanometer of higher concentration in metal phase 525 compared with entire material at surface or near it
Particle 510.
Fig. 6 depicts some embodiments, these embodiments start from being distributed in metal matrix 605 in advance (such as in ingot)
In nanoparticle 610.It can be obtained by heating the functionalised powder containing the metal micro particle for being coated with nanoparticle
Ingot, as shown in Figs 1-4.Ingot is applied heat to, which undergoes the mutually separation of density-driven, wherein melting since density is greater than
Change the density of matrix 615, nanoparticle 610 is migrated far from surface (on gravity direction).After solidification, gained functionally gradient
Metal matrix nanocomposite is in metal phase 625 compared with entire material at the distal region far from surface or near it
Nanoparticle 610 containing higher concentration.
Fig. 7 depicts some embodiments, these embodiments start from being distributed in metal matrix 705 in advance (such as in ingot)
In total dispersing nanoparticles 710 and 720.It can be by heating the function containing the metal micro particle for being coated with nanoparticle
Change powder and obtain ingot, as shown in Figs 1-4.Ingot is applied heat to, which undergoes the mutually separation of density-driven, wherein due to
Density is greater than the density of fusing matrix 715, and nanoparticle 710 is migrated far from surface (on gravity direction), simultaneously because density
Less than the density of fusing matrix 715, nanoparticle 720 is migrated towards surface (resisting gravity).After solidification, gained function ladder
Spend metal matrix nanocomposite in metal phase 725 with entire material compared at the distal region on separate surface or its is attached
The closely nanoparticle 710 containing higher concentration, and the nanoparticle 720 at surface or near it containing higher concentration.
Fig. 8 depicts some embodiments, these embodiments start from being distributed in metal matrix 805 in advance (such as in ingot)
In total dispersing nanoparticles 810 and 820.It can be by heating the function containing the metal micro particle for being coated with nanoparticle
Change powder and obtain ingot, as shown in Figs 1-4.Ingot is applied heat to, which undergoes the mutually separation of density-driven, wherein due to
Density is greater than the density of fusing matrix 815, and nanoparticle 810 is migrated far from surface (on gravity direction).In this embodiment,
Since density is greater than the density of fusing matrix 815, nanoparticle 820 is also migrated far from surface (on gravity direction), but nanometer
The density of particle 820 is less than the density of nanoparticle 810.Therefore, compared with nanoparticle 810, nanoparticle 820 is kept more
It is dispersed in fusing metal matrix 815.After solidification, gained functionally graded metal matrix matter nanocomposite is in metal phase
810 He of nanoparticle in 825 compared with entire material at the distal region far from surface or near it containing higher concentration
Both 820.The gradient of 810/820 concentration of nanoparticle is different.
Fig. 9 depicts some embodiments, these embodiments start from being distributed in metal matrix 905 in advance (such as in ingot)
In total dispersing nanoparticles 910 and 920.It can be by heating the function containing the metal micro particle for being coated with nanoparticle
Change powder and obtain ingot, as shown in Figs 1-4.Ingot is applied heat to, which undergoes the mutually separation of density-driven, wherein due to
Density is less than the density of fusing matrix 915, and nanoparticle 910 is migrated towards surface (resisting gravity).In this embodiment, due to
Density is less than the density of fusing matrix 915, and nanoparticle 920 is also towards surface migration, but the density of nanoparticle 920 is greater than and receives
The density of rice corpuscles 930.Therefore, compared with nanoparticle 910, nanoparticle 920 is more dispersed in fusing metal matrix 915
It is interior.After solidification, gained functionally graded metal matrix matter nanocomposite in metal phase 925 compared with entire material in table
The two of nanoparticle 910 and 920 at face or near it containing higher concentration.The gradient of 910/920 concentration of nanoparticle is not
With.
Figure 10 is according to the transversal of the exemplary AlSi10Mg-WC functionally graded metal matrix matter nanocomposite of example 1
The SEM image (describing in the following example) in face (side view).
Master alloy metal matrix nanocomposite
" master alloy " is clearly defined in the art, and refer to can be added in the metal processed with will
Appropriate alloying element is introduced into the concentration alloy source in system.When alloying element is difficult to disperse or weight is low, master alloy is special
Useful.In the case where difficulties in dispersion, pre-dispersed master alloy increases wetability and avoids agglomeration.The low weight the case where
Under, when heavier pre-alloyed materials can be added, it is easier to control addition, to avoid the weighting error of secondary alloying element.
" master alloy metal matrix nanocomposite " or equally " master alloy nanocomposite " is here and hereinafter meant that
A kind of metal matrix nanocomposite has the nanometer being distributed in metal or metal alloy matrix greater than 0.1wt%
Particle is suitable for being further processed into final products by various different approaches (melt processing, machining, forging etc.).Nanometer
The concentration of particle is typically at least 1wt%.
In some modifications of the invention, functionally graded metal matrix matter nanocomposite is manufactured, then from nano combined
The one or more phases for being free of nanoparticle are removed in material, to generate master alloy metal matrix nanocomposite.
The production of master alloy metal matrix nanocomposite allows largely to load to reinforced phase in metal matrix.Pass through
Evenly dispersed nanoparticle reinforced phase is consolidated, the mutually separation of density-driven is such as passed through, and then removes and is free of nanoparticle
The part of reinforced phase obtains master alloy.Master alloy can be used for being further processed to generate final geometric configuration, such as melt plus
Work and casting.
These methods provide the master alloy metal matrix nanocomposite of low cost, mass production, have a large amount of
The nanoparticle reinforced phase of load.It can by using pre-dispersed metal matrix nanocomposite raw material powder or raw material ingot
So that the reaction time minimizes.
Some modifications of the invention provide a kind of method for preparing master alloy metal matrix nanocomposite, this method packet
It includes:
(a) the ingot composition comprising metalliferous micro particles and nanoparticle is provided, wherein nanoparticle chemistry and/or object
Reason ground is arranged on the surface of micro particles, and wherein nanoparticle spreads ingot composition with three-dimensional construction consolidation;
(b) the ingot composition is melted to form melt, and wherein the melt separation is at first comprising metalliferous micro particles
Phase and the second phase comprising nanoparticle;
(c) solidify the melt to obtain metal matrix nanocomposite, there is at least one for passing through nanocomposite
The concentration gradient of the nanoparticle of dimension;And
(d) it compared with the rest part of metal matrix nanocomposite, removes a part and contains low concentration nanoparticle
Thus metal matrix nanocomposite generates master alloy metal matrix nanocomposite.
Micro particles can contain element selected from the group below, which be made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si,
And combinations thereof.Nanoparticle can contain compound selected from the group below, which be made up of: metal, ceramics, cermet,
Intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon, and combinations thereof.In certain embodiments, micron
Particle contains Al, Si and Mg, and nanoparticle contains tungsten carbide (WC).
Processing in step (b) and (c) as raw material and is produced using pre-dispersed ingot or other starting ingot compositions
Raw functionally graded metal matrix matter nanocomposite.
Step (b) may further include compacting, sintering, mixing, dispersion, Friction Stir Welding, extrusion, bonding, capacitor
Discharge sintering, casting, or combinations thereof.Step (b) may include keeping effective stay time (for example, about 1 minute to 8 melt
Hour) to cause the separation of the first phase with the density-driven of the second phase.Optionally, step (b) may include being exposed to melt
Selected from gravity, centrifugation, machinery, electromagnetism, or combinations thereof external force.
If desired, then step (c) may include the directional solidification or consecutive solidification of melt.Directional solidification is from casting
Distalmost end occurs, and advances and be introduced into the solidification in the channel in mold towards wherein fluent material.Consecutive solidification is from casting
The wall solidification that starts and vertically advance from the surface.
The concentration gradient of first nanoparticle can be present in metal matrix nanometer at least 100 microns of length scale
In composite material.
In some embodiments, metal-matrix phase and the first reinforced phase respectively spread metal matrix nanocomposite point
It dissipates.In these or other embodiments, metal-matrix phase and the first reinforced phase are multiple in metal matrix nanometer with layered configuration setting
In condensation material, wherein the layered configuration includes at least first layer comprising nanoparticle and at least the comprising metal-matrix phase
Two layers.
Step (d) may include processing, ablation, reaction, dissolution, evaporation, selective melting, or combinations thereof.In certain realities
It applies in example, step (d) provides two different master alloy metal matrix nanocomposites.Many heating means and residence time
The production of master alloy metal matrix nanocomposite suitable for density-driven.
In some embodiments, a kind of method manufacturing master alloy metal matrix nanocomposite begins with pre- point
Scattered ingot is as the raw material with metal component and enhancing particle.The ingot is set to enter liquid or semi-solid phase by processing,
Middle metal component and the enhancing component (nanoparticle) of dispersion enter fusing fluid or semi-solid phase together.
In some embodiments, enhancing component is separated by the separation of density-driven.Specifically, matrix immobilized and increase
Strong component is by Density Separation at the fraction of one or more higher volumes (with discrete phase ratio).Then it at least partly removes whole
The low volume fraction component of a solid, to leave the final production with high-volume fractional master alloy metal matrix nanocomposite
Object.
According to one or more matrix metals or one or more metal alloys with arbitrarily form nanoparticle (including its
His metal or metal alloy) combined selection, the composition of the master alloy is widely varied.Enhance the size of nanoparticle preferably
Less than 1000nm, even more preferably less than 250nm, have any geometric configuration (stick, ball, prism etc.).Note that the low-density removed
Material can recycle and for subsequent processing.By producing the mother that can be added in the subject alloy system in molten state
Alloy can produce fully decentralized metal matrix nanocomposite, and then in conventional, cost-effective high temperature smelting
It is processed in golden method.
In some embodiments, the metal matrix nanocomposite in step (c) is characterized in that cast microstructure.
One or more final master alloy metal matrix nanocomposites can have cast microstructure.The spy of cast microstructure
Sign is that it includes the crystal boundary in multiple dendrite (from crystal growth) and microstructure.In some embodiments, there is also more
A gap, but it is preferably without crack or big phase boundary.
In some embodiments, cast microstructure is further characterized by equiaxial fine grain microstructure.It is isometric
The length of crystal grain, width and height are roughly equal.When exist by be included in micro particles surface on, functionalization raw metal
In and when many nucleation sites that therefore multiple nanoparticles in master alloy metal matrix nanocomposite generate, can be with
Generate equi-axed crystal.
In some embodiments, the microstructure for being further characterized by dispersion of cast microstructure.That disperses is microcosmic
Structure usually by microstructure a large amount of dendrite and crystal boundary generate, again initially by a large amount of nanoparticles on micro particles surface
Son generates.Degree of scatter can be characterized by breakup length scale, which is calculated as between nanoparticle
Average headway and/or nanoparticle between metal phase in average length scale.In various embodiments, breakup length mark
Degree is from about 1 nanometer to about 100 micron, such as from about 10 nanometers to about 10 micron, or about 100 nanometers to about 1 micron.
It is optionally possible to which porosity is removed or reduced in cast microstructure.For example, can carry out reheating and/
Or pressurization (or other mechanical forces) handles so that porous gap present in metal matrix nanocomposite minimizes.In addition,
It can be by physically removing (for example, excision) separated region in porous gap (the mutually separation as passed through density-driven) from gold
Belong in substrate nano composite material and removes hole.Compared with the region of removing, it is desirable to master alloy can have less gap or
There is no gap.
Other than removing gap, other post-processings can be carried out, it is possible to create be not cast microstructure, or contain
Other final microstructures of microstructure mixture.For example, forging can improve the defect of ingot casting or continuous rod casting, and such as
Fruit wishes that other direction intensity can be introduced.Preprocessing (for example, strain hardening) can be carried out, is needing maximum strong to generate
The grain flow that the side of degree is upwardly oriented.Therefore, in certain embodiments, master alloy microstructure can be forging microstructure,
Or mixing casting/forging microstructure.In various embodiments, it is based on volume, master alloy metal matrix microstructure is at least
10%, 25%, 50%, 75%, 90%, 95%, 99% or 100% cast microstructure.
Master alloy may finally be processed in various parts.These components can be produced by various techniques, and therefore
Final component can have or not have cast microstructure.Metal parts shaping operation includes but is not limited to forge, rolling, squeeze
Out, drawing, sand casting, die casting, model casting, powder metallurgy, welding, increasing material manufacturing etc..It may want in final component
Cast microstructure, or may want to different microstructures, such as forge microstructure.In some embodiments, master alloy
Cast microstructure may be preferred for the performance and quality of final component.
Figure 11 to 15 shows several non-limiting embodiments of master alloy metal matrix nanocomposite.
Figure 11 is the cross section according to the exemplary AlSi10Mg-WC master alloy metal matrix nanocomposite of example 2
The SEM image (describing in the following example) of (side view).
Figure 12 depicts some embodiments, these embodiments start from being distributed in metal matrix 1205 in advance (such as in ingot
In) in nanoparticle 1210.Ingot is applied heat to, which undergoes the mutually separation of density-driven, wherein since density is small
In the density of fusing matrix 1215, nanoparticle 1210 is migrated towards surface (resisting gravity).After solidification, gained function ladder
Degree metal matrix nanocomposite contains compared with entire material more highly concentrated in metal phase 1225 at surface or near it
The nanoparticle 1210 of degree.Then remove solid 1225 a part, with relatively low concentration nanoparticle 1210 (or
Nanoparticle not as shown in this figure).The result is that being rich in the master alloy metal of nanoparticle 1210 in metal matrix 1225
Substrate nano composite material.
Figure 13 depicts some embodiments, these embodiments start from being distributed in metal matrix 1305 in advance (such as in ingot
In) in nanoparticle 1310.Ingot is applied heat to, which undergoes the mutually separation of density-driven, wherein since density is big
In the density of fusing matrix 1315, nanoparticle 1310 is migrated far from surface (on gravity direction).After solidification, gained function
Energy graded metal matrix nanocomposite is in metal phase 1325 compared with entire material at the distal region far from surface
Or the nanoparticle 1310 containing higher concentration near it.Then a part for removing solid 1325, with relatively low dense
The nanoparticle 1310 (or nanoparticle not as shown in this figure) of degree.The result is that being rich in nanoparticle in metal matrix 1325
The master alloy metal matrix nanocomposite of son 1310.
Figure 14 depicts some embodiments, these embodiments start from being distributed in metal matrix 1405 in advance (such as in ingot
In) in total dispersing nanoparticles 1410 and 1420.Ingot is applied heat to, which undergoes the mutually separation of density-driven,
In due to density be greater than fusing matrix 1415 density, nanoparticle 1410 far from surface (on gravity direction) migrate.At this
In embodiment, since density is greater than the density of fusing matrix 1415, nanoparticle 1420 is also far from surface (on gravity direction)
Migration, but the density of nanoparticle 1420 is greater than the density of nanoparticle 1410.After solidification, gained functionally graded metal matrix
Matter nanocomposite contains at the distal region far from surface or near it compared with entire material in metal phase 1425
Both nanoparticles 1410 and 1420 of higher concentration.Then a part for removing solid 1425, with relatively low concentration
Nanoparticle 1410/1420 (or nanoparticle not as shown in this figure).It is received the result is that being rich in metal matrix 1425
The master alloy metal matrix nanocomposite of rice corpuscles 1410 and 1420.Note that the layered configuration in Figure 14 be it is possible, because
Density for nanoparticle 1410 and 1420 is different.In other embodiments, when density is same or similar, nanoparticle
1410 and 1420 will tend to be evenly dispersed in final master alloy metal matrix nanocomposite.
Figure 15 depicts some embodiments, these embodiments start from being distributed in metal matrix 1505 in advance (such as in ingot
In) in total dispersing nanoparticles 1510 and 1520.Ingot is applied heat to, which undergoes the mutually separation of density-driven,
In due to density be greater than fusing matrix 1515 density, nanoparticle 1510 far from surface (on gravity direction) migrate, simultaneously
Since density is less than the density of fusing matrix 1515, nanoparticle 1520 is migrated towards surface (resisting gravity).After solidification,
Gained functionally graded metal matrix matter nanocomposite is in metal phase 1525 in the distal side far from surface compared with entire material
At region or its neighbouring nanoparticle 1510 containing higher concentration, and receiving containing higher concentration at surface or near it
Rice corpuscles 1520.Then remove solid 1525 a part, with relatively low concentration nanoparticle 1510/1520 (or
Nanoparticle not as shown in this figure).Two different master alloy metal matrix nanocomposites are manufactured simultaneously.A kind of mother
Alloying metal substrate nano composite material is rich in nanoparticle 1510 in metal matrix 1525.Another master alloy metal matrix
Nanocomposite is rich in nanoparticle 1520 in metal matrix 1525.
For producing the functional metal raw material of metal matrix nanocomposite
Dusty material is the raw material of the general type for powder metallurgical technique, which includes but is not limited to increase material system
It makes, injection-molded and compacting and sintering are applied.As contemplated herein, " dusty material " refers to any powdered ceramic, gold
Category, polymer, glass or composite material or combinations thereof.In some embodiments, dusty material is metal or metal-containing compound,
But this disclosure should not be construed as being limited to intermetallic composite coating.Powder size is typically at about 1 micron between about 1mm, but one
It can up to 1cm in a little situations.
Dusty material can be any form, and wherein discrete particle can suitably be differentiated with block.Powder material
Material is not always to be observed as bulky powder, and can be used as paste, suspension or green compact and exist.Green compact are in this way
A kind of object, its main component is the dusty material of faint combination before fusing and solidification.For example, welding electrode can be by
It is pressed into the dusty material composition of available club.
Particle can be it is solid, hollow, or combinations thereof.Particle can be prepared by any means, these means packets
Include such as gas atomization, grinding, cryogrinding, wire explosion (wireexplosion), laser ablation, electro-discharge machining or sheet
Other technologies known to field.Powder particle can be characterized as the average aspect ratio from about 1:1 to about 100:1." draw ratio " meaning
Refer to particle length: the ratio of width is expressed as length: width.The perfect spherical draw ratio with 1:1.For any geometry
The particle of shape, length is maximum effective diameter, and width is minimum effective diameter.
In some embodiments, these particles are in club shape." club " means shaped like long rod, dowel or needle
The stick particle of shape object or domain.The average diameter of club can be for example selected from about 5 nanometers to about 100 microns.Club is not required to
If perfect cylindrical body, that is, axis is not necessarily straight and diameter and is not necessarily perfect circle.Geometrically faulty
In the case where cylindrical body (that is, being inaccurately d-axis or round diameter), draw ratio is along the practical axial long of its line of curvature
For degree divided by effective diameter, which is the circle with area identical with the averga cross section area of the practical nanorod shape
Diameter.
Dusty material particle can be anisotropic.As intended by this paper, " anisotropic " particle, which has, to be depended on
At least one chemically or physically characteristic in direction.When along different shaft centerline measurements, anisotropic particles will have measurable characteristic
Some variations.The characteristic substantially can be (for example, geometry) or chemistry of physics, or both.Along multiple axis
The characteristic of variation can be only that there are ontologies;For example, perfect sphere will be geometrically isotropic, and cylindrical body is several
What is upper anisotropic.Chemically or physically the variable quantity of characteristic can be 5%, 10%, 20%, 30%, 40%, 50%, 75%,
100% or more.
" solidification " typically refers to the phase change from liquid to solid.In some embodiments, solidification refers in powder volume
Whole intracorporal phase change.In other embodiments, solidify and refer in particle surface or in the dusty material of a volume fraction
Phase change.In various embodiments, make at least (by volume) 1%, 2%, 5%, 10%, 15%, 20%, 25%, 30%,
40%, 50%, 60%, 70%, 80%, 90%, 95%, 99% or 100% dusty material is melted to form liquid.
For metal or metal mixture, solidification generally produces one or more solid metal phases, they are typically
It is crystallization, but sometimes unsetting.Ceramics can also undergo crystallisation solidification or unsetting solidification.Metal and ceramics can be simultaneously
Form unsetting region and crystal region (for example, in those semi-crystalline materials).In the case where certain polymer and glass, solidification
It may not lead to crystallisation solidification.If forming unsetting solid from liquid, solidification refers to from the case where being higher than glass transformation temperature
Liquid be changed into the unsetting solid under glass transformation temperature.Glass transformation temperature is not always well to limit
, and it is characterized as temperature range sometimes.
" surface functionalization " refers to the surface modification on dusty material, which significantly affects the solidification row of dusty material
For (for example, solidification rate, yield, selectivity, heat release etc.).In various embodiments, dusty material functionalised as the powder
Last shape material about 1%, 2%, 5%, 10%, 15%, 20%, 25%, 30%, 40%, 50%, 60%, 70%, 80%,
85%, 90%, 95%, 99% or 100% surface region is modified with surface functionalization.Surface modification may be surface chemistry
Modification, physical surface modification, or combinations thereof.
In some embodiments, surface functionalization includes nanoparticle coating and/or micro particles coating.Nanoparticle
And/or micro particles may include metal, ceramics, polymer or carbon or composite material, or combinations thereof.Surface functionalization can be with
Including the particle component to be chemically or physically arranged on dusty material surface.
Since the size of nanoparticle is small and their reactivity, benefit provided herein can be by less than 1% surface district
Domain coverage ratio is realized.In the case where nanoparticle functionalization identical with basic powder with composition, surface chemistry variation may
It can not detect, and can be characterized for example, by the topological variation on surface.For example, with composition nanometer identical with basic powder
Particle functionalization can be used for reducing fusing point, to start to be sintered at a lower temperature.
In some embodiments, micro particles coating micrometer powder or big powder.Micron powder or big powder particle can be with
Including ceramics, metal, polymer, glass, or combinations thereof.Micro particles (coating) may include metal, ceramics, polymer, carbon,
Or combinations thereof.In the case where micro particles are coated with other micron of powder or big powder, functionalization preferably means coated particle
It is dramatically different with the size of basic powder.For example, micro particles, which can be characterized as average-size (for example, diameter), is less than coating powder
Maximum sized 20%, 10%, 5%, 2% or 1% at end.
In some embodiments, surface functionalization is in the form of continuous coated or interval coating.Continuous coated covering is at least
90% surface, the surface (recognize on surface can defective, gap or impurity) of such as from about 95%, 99% or 100%.Between
Coating of having a rest is discontinuous, and cover be less than 90%, such as from about 80%, 70%, 60%, 50%, 40%, 30%, 20%,
10%, 5%, 2%, 1% or less surface.Interval coating can be uniform (for example, having certain repetitions to scheme on surface
Case) or it is non-uniform (for example, random).
In general, coating can be continuous or discontinuous.Coating can have several property features.In one embodiment
In, coating can be surface that is smooth, and complying with lower section.In another embodiment, coating is tubercular.Nodositas is raw
Length is dynamic (dynamical) feature of nucleation and growth.For example, coating can look like from surface grow cauliflower or it is small not
Regular crumb form.These features may be influenced by underlying materials, coating method, reaction condition etc..
Coating may or may not be in nanoparticle or micro particles form.That is, coating can be originated from nanoparticle
Son or micro particles, and can no longer have discrete nanoparticle or micro particles.Various coating techniques can be used, such as
(but being not limited to) electroless deposition, immersion deposition or solution coating.Coating layer thickness is preferably less than about the 20% of lower section particle diameter,
Such as less than 15%, 10%, 5%, 2% or the 1% of lower section particle diameter.
In some embodiments, surface functionalization further includes directly chemically or physically modifying for dusty material surface, is such as used
To improve the combination of nanoparticle or micro particles.It can also be using the direct chemical modification on dusty material surface (such as addition point
Son) influence dusty material curing action.A variety of surface modifications as described herein can be used simultaneously.
Nanoparticle is particle of the full-size between about 1nm and 1000nm.The preferred size of nanoparticle is less than
250nm, even more preferably less than 100nm.Micro particles are particle of the full-size between about 1 micron and 1000 microns.Nanometer
Particle or micro particles can be such as metal, ceramics, polymer, carbon-based or composite particles.Nanoparticle or micron grain
Sub- size can be determined with expected characteristics component-based and final function.
It is typically no more than above maximum sized spherical or any that nanoparticle or micro particles can be full-size
Shape.Exception is that have the structure of high draw ratio, such as carbon nanotube, and wherein size may include that length is up to 100 microns, and
Diameter is less than 100nm.Nanoparticle or micro particles may include the coating with one or more layers different materials.It can be used
The mixture of nanoparticle and micro particles.In some embodiments, micro particles itself pass through nanoparticle coating, and micro-
Rice corpuscles/nano composition is incorporated on dusty material particle as coating or layer.
Some modifications provide a kind of dusty material comprising multiple particles, and wherein these particles are by the first material (example
Such as, ceramics, metal, polymer, glass, or combinations thereof) be made, and wherein each of these particles have use nanoparticle
And/or micro particles carry out the particle surface area of surface functionalization (as continuously or intermittently), these nanoparticles and/or micro-
Rice corpuscles be selected as controlling the dusty material from liquid curing be solid-state.Nanoparticle and/or micro particles may include
Metal, ceramics, polymer, carbon, or combinations thereof.
In some embodiments, dusty material be characterized in that an average of at least 1%, 2%, 5%, 10%, 15%,
20%, 25%, 30%, 35%, 40%, 45%, 50% or more particle surface area is with nanoparticle and/or micron grain
Son has carried out surface functionalization.
In some embodiments, nanoparticle and/or micro particles are selected as controlling a part of dusty material
Solidification, the part such as dusty material wish to control cured region.There may be being free of containing conventional powders shape material to receive
Other of rice corpuscles and/or micro particles region.In some embodiments, nanoparticle and/or micro particles are selected as controlling
Make the solidification of a part (for example, being less than the whole volume of particle, such as shell) of each particle.
A variety of materials combination is equally possible.In some embodiments, powder particle be ceramics, and nanoparticle and/
Or micro particles are ceramics.In some embodiments, powder particle is ceramics, and nanoparticle and/or micro particles are gold
Belong to.In some embodiments, powder particle is polymer, and nanoparticle and/or micro particles are metal, ceramics or carbon-based
's.In some embodiments, powder particle is glass, and nanoparticle and/or micro particles are metals.In some embodiments
In, powder particle is glass, and nanoparticle and/or micro particles are ceramics.In some embodiments, powder particle is pottery
Porcelain or glass, and nanoparticle and/or micro particles are polymer or carbon-based etc..
The exemplary ceramics material of powder or nanoparticle and/or micro particles include but is not limited to SiC, HfC, TaC,
ZrC、NbC、WC、TiC、TiC0.7N0.3、VC、B4C、TiB2、HfB2、TaB2、ZrB2、WB2、NbB2、TaN、HfN、BN、ZrN、TiN、
NbN、VN、Si3N4、Al2O3、MgAl2O3、HfO2、ZrO2、Ta2O5、TiO2、SiO2And rare earth element y, La, Ce, Pr, Nd,
The oxide of Sm, Eu, Gd, Tb, Dy, Ho Er, Tm, Yb, and/or Lu.
The examples metallic materials of powder or nanoparticle and/or micro particles include but is not limited to Sc, Ti, V, Cr,
Y、Zr、Nb、Mo、Ru、Rh、Pd、La、Ce、Pr、Nd、Sm、Eu、Gd、Tb、Dy、Ho Er、Tm、Yb、Lu、Ta、W、Re、Os、Ir、
Pt, Si or B.
The exemplary polymer of powder or nanoparticle and/or micro particles includes but is not limited to that thermoplasticity is organic
Or inorganic polymer or thermosetting property is organic or inorganic polymer.Polymer can be natural or synthesis.
The exemplary glass material of powder includes but is not limited to silicate glass, porcelain, vitreous carbon, polymeric thermoplastic material
Material, metal alloy, glassy state ionic liquid, ion melt and glassy molecular liquid.
The exemplary carbon or carbon-based material of nanoparticle and/or micro particles include but is not limited to graphite, activated carbon, stone
Black alkene, carbon fiber, carbon nano-structured (for example, carbon nanotube) and diamond (for example, Nano diamond).
The material of these classifications is not mutually exclusive;Such as given material can be metal/ceramic, glass-ceramic,
Polymer glass etc..
The selection of coating/powder constituent will depend on expected characteristics, and should concrete condition specifically consider.Material science
Or the technical staff in metallurgy field will select according to the information provided in this disclosure for being expected the appropriate of technique
Material.Processing and final products configuration should also be as depending on expected characteristics.Material science, metallurgy, and/or mechanical engineering field
Technical staff will be according to the information selection provided in this disclosure for wishing the appropriate processing conditions of result.
In some embodiments, a kind of cured method controlling dusty material includes:
A kind of dusty material comprising multiple particles is provided, wherein these particles are made of the first material, and wherein this
Each of a little particles have the particle surface area that surface functionalization is carried out with nanoparticle and/or micro particles;
At least part of the dusty material is molten into liquid;And
Control semi-passively the dusty material from the liquid curing be solid-state.
As desired in this explanation, the terms such as " semi-passive control ", " controlling semi-passively " refer to surface function
The dusty material of change is heated, cooled down or heated and cooling period control solidification, wherein passing through selected official before melting
Energyization solidifies not after once fusing-solidification process by external active control to design solidification control.Note that being not necessarily to
Avoid external reciprocation.In some embodiments, cured semi-passive control further includes selection atmosphere (for example, pressure, wet
Degree or gas composition), temperature or heat input or output.These factors and those skilled in the art it is known other
Factor can with or cannot be included in semi-passive control.
The exemplary semi-passive control process that elaboration is realized by surface functionalization as described herein now.
It is a kind of control nucleation approach be by be originated from coating described above nanoparticle be introduced into liquid phase.Nanoparticle
Son may include above-mentioned any material composition, and can be selected based on the wet ability into melt.After fusing starts, nanometer
Particle is moistened as dispersed particle into melting tank, after cooling, serves as nucleation site, can be observed to generate and have in cross section
The acinose texture of the nucleation site arrived.In some embodiments, the density of nucleation site increases, and solidifies the number in forward position due to growing
Nucleation energy barrier is measured and lacks, this can increase volume freezing rate.
In the exemplary embodiment, by ceramic nanoparticle (such as TiB2Or Al2O3Nanoparticle) to be coated on aluminium alloy micro-
On rice corpuscles.Ceramic nanoparticle is introduced into aluminum alloy melting pond in increasing material manufacturing technique.Then nanoparticle is melting
Disperse in pond, and serves as the nucleation site of solid.Other fully dispersed nucleation sites can mitigate contraction fissure (hot tearing).When
When liquid is unable to reach some regions due to solidifying the barrier of intercrystalline slype, typically there is contraction fissure.It is nucleated position
The increase of point can prevent from forming narrow long-channel between crystal grain solidifying, because multiple little crystal grains are being grown, rather than it is several
A big crystal grain is being grown.
In another exemplary embodiment, nanoparticle serves as the nucleation site of time phase in the alloy.Nanoparticle can
With the material (for example, since crystal structure is similar) for including time phase or being nucleated time phase.If secondary phase, which can block, leads to hot tearing
Interdendritic channel, then the embodiment can be beneficial.By making many times phase little crystal grain nucleation, can be blocked to avoid possible
The big crystal grain of interdendritic slype.In addition, if secondary phase is easy to form continuous phase between first phase crystal grain, this can promote stress
Corrosion cracking, the embodiment can be beneficial.By mutually providing other nucleation sites to be secondary, this time can be destroyed mutually and be allowed to
Disperse in centre, to prevent it from forming continuous phase between primary alloy grain.By destroying time phase during curing, have latent
A possibility that power more competitively makes material homogenize during heating treatment, this can reduce stress corrosion cracking (homogenizes
Gradient is less in material).If secondary mutually discontinuous, it is less likely to corrosion and long recess occurs.
In another embodiment of control nucleation, functionalized surfaces can dissolve completely or partially in the melt,
And undergo and reacted with the material in melt to form sediment or content, this can be by identical as nanoparticle in earlier paragraphs
Mode work.For example, titanium particle can be coated on aluminium alloy particle, titanium will be dissolved after being melted down.However, cold
When but, material undergoes peritectic reaction, so that aluminium-titanium intermetallic compound (Al of nucleation site will be served as by being formed3Ti) content.
In another embodiment, coating can be reacted with impurity to form nucleation site.Example is on titanium alloy powder
Magnesium coating.Titanium has very high oxygen solubility (common atmosphere pollution), this will affect overall characteristic.Magnesium coating and molten
Precursor reactant is bound to dissolved oxygen, magnesia (MgO) content is formed, to promote nucleation.
Controlling nucleation may include using ceramic particle.In some embodiments, ceramic particle can pass through fusing
Material wetting, and in other embodiments, ceramic particle can not be soaked by molten material.Ceramic particle can be mixed with molten state
It is molten or unmixing.Ceramic particle can be mixed in final solid material.In some embodiments, ceramic particle and solid repel.
Exemplary ceramics material includes but is not limited to SiC, HfC, TaC, ZrC, NbC, WC, TiC, TiC0.7N0.3、VC、B4C、TiB2、
HfB2、TaB2、ZrB2、WB2、NbB2、TaN、HfN、BN、ZrN、TiN、NbN、VN、Si3N4、Al2O3、MgAl2O3、HfO2、ZrO2、
Ta2O5、TiO2、SiO2And rare earth element y, La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho Er, Tm, Yb, and/or Lu
Oxide.
Controlling nucleation may include using metallic.In some embodiments, metallic can pass through fusing
Material wetting.Metallic can form alloy by eutectic reaction or peritectic reaction with molten material.Alloy can be metal
Between compound or solid solution.In some embodiments, metallic cannot be soaked by molten material, and can not be with fusing material
Material forms alloy.Examples metallic materials include but is not limited to Sc, Ti, V, Cr, Y, Zr, Nb, Mo, Ru, Rh, Pd, La, Ce,
Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho Er, Tm, Yb, Lu, Ta, W, Re, Os, Ir, Pt, Si or B.
Controlling nucleation may include using plastic pellet.In some embodiments, plastic pellet can be by fusing material
Material wetting, and in other embodiments, plastic pellet can not be soaked by molten material.
Nanoparticle promotes plane of crystal growth, has good extension stickiness.When nanoparticle and curing materials
When having good fit between crystal lattice parameters, the nucleation possibility in nanoparticle surface is higher.It can be by nanoparticle
Son, which is selected as, promotes the nucleation of specific phase in the melt.
In general, the chemical reaction of nucleation is promoted to depend on selected surface functionalization and heating (or cooling) ginseng
Number.
When nanoparticle or micro particles in rapid melting or occur close to fusing and with few melt convection particle is fast
Speed be fused together under conditions of when being organized on particle surface, coating will be spread without time or correlation energy far from its phase
For the initial position of other powder.This will generate the three-dimensional net structure of content in turn.Therefore it provides a kind of control is maximum
Crystallite dimension and/or the method for designing predictable microstructure.Microstructure depends on initial powder size, shape and filling
Configuration/density.Adjustment coating and powder parameter allow to control the layered structure.In some embodiments, these constructions pass through resistance
Hinder, prevent or redirect the dislocation motion on specific direction and significantly improve material property, to reduce or eliminate inefficacy mechanism.
Using appropriate functionalization, fusing heat or the hot-fluid between evaporation thermal control curing time can be used.In some embodiments,
Content is pulled in melt, or reacts (as described above) in melt.In some embodiments, coating repels the table of melting tank
Face.It, with the functionalized surfaces of high-vapor-pressure, will be evaporated using under desired melting point, generate cooling in the melt
Effect increases cooling rate.As described above, this may be implemented in the magnesium on titanium alloy in addition to forming oxide content
Point.This effect under relatively the same terms nonfunctionalized powder and functionalised powder and compared with feed composition and final produce
It is detected when the composition of product.
In another embodiment, there is reverse effect.Some systems may be needed can be with than in certain production systems
The slower curing time rationally provided.In this example, materials with high melting point (such as can repel surface) solidifies.This just will fusing
Heat is discharged into system, to slow down total heat flux outflow melt.Can also have the of significant more high heat capacity by mixing
Two materials keep heat in the melt, to slow down solidification.
In another embodiment, the hot-fluid during melting tank forms and/or solidifies is controlled using heat is formed.For example,
Nickel micro particles can be modified with aluminum nanoparticles.When supplying enough activation energy, the exothermic reaction of Ni and Al to NiAl is triggered.?
In this case, release is a large amount of forms hot (- 62kJ/mol), this helps to melt particle completely or partially.By gained NiAl gold
Compound is absorbed into melt between category, and because its higher melt keeps suspending (a part may dissolve) as solid, thus
There is strengthening effect as nucleation site, and to later alloy.
Cured balance controlled can use nanoparticle/micro particles or surface covering, they, which undergo, is different from base
The phase transformation of phase transformation in body material.Phase transformation can occur under different solidus and/or liquidus temperature, in similar solidus
And/or under liquidus temperature or under identical solidus and/or liquidus temperature.Nanoparticle/micro particles of phase transformation or
Surface covering can mix in final solid material, or can repel final solid material, or both can be with.Phase transformation is received
Rice corpuscles/micro particles or surface covering can be miscible or unmixing with molten state.Nanoparticle/the micro particles or table of phase transformation
Finishing coat can be miscible or unmixing with solid-state.
Cured balance controlled can use the nanoparticle/micro particles or surface covering of evaporation or part evaporation.
For example, this type coating may include organic material (for example, wax, carboxylic acid etc.) or inorganic salts (for example, MgBr2、ZnBr2Deng).
Cured balance controlled can use release or absorb receiving for gas (for example, oxygen, hydrogen, carbon dioxide etc.)
Rice corpuscles/micro particles or surface covering.
Cured balance controlled can use nanoparticle/micro particles or surface of the thermal capacity different from basis material
Coating.
Except by energy hole in systems in addition to, control thermal conductivity or emissivity (hot IR radiation) control heat can also be passed through
Leave the rate of system.Such control can be for example originating from the repulsion to surface or the heat from the powder bed during increasing material manufacturing
Conductance.In one embodiment, functionalization can repel surface, a kind of low thermal conductivity material, which can directly be function
Change material or its reaction product, the functionalised materials or its reaction product completely cut off lower section melt and reduce freezing rate.?
In other embodiments, layer can have high/low emissivity, this is by increase/into and out system of reduction radiant heat flux.These realities
Example is applied especially suitable for the electron beam system under vacuum, and therefore radiation is major heat flow mechanism.
In addition, the emissivity of exclusion layer can be used to control defeated under given laser radiation wavelength in laser sintering system
Enter the amount of the energy of powder bed.In another embodiment, functionalized surfaces can be fully absorbed in the melt, but close to its
He is unfused functionalised powder, and the heat transfer outside system can be changed such as the increasing material manufacturing in powder bed.This may indicate that this
Body is the lower thermal conductivity basis powder with high heat conductance coating.
Cured thermal conductivity or emissivity control the available higher nanoparticle/micron of the thermal conductivity compared with basis material
Particle or surface covering.Nanoparticle/micro particles or surface covering can mix in melt, or can repel such as crystal boundary or melt
Body surface face.Nanoparticle/micro particles or surface covering can be miscible or unmixing with molten state.Nanoparticle/micro particles
Or surface covering can be miscible or unmixing with final solid-state.
Cured thermal conductivity or emissivity control can use the lower nanoparticle of the thermal conductivity compared with basis material/micro-
Rice corpuscles or surface covering.
Cured thermal conductivity or emissivity control can use the higher nanoparticle of the emissivity compared with basis material/micro-
Rice corpuscles or surface covering.
Cured thermal conductivity or emissivity control can use the lower nanoparticle of the emissivity compared with basis material/micro-
Rice corpuscles or surface covering.
In some embodiments, functionalised materials can be with the pollutant reaction in melt (for example, Mg-Ti-O system).
When appropriately selection functionalised materials, the material of reaction can choose, so that the reaction product and liquid that are formed have high surface
Tension allows it to repel surface.The reaction product of repulsion can be in squame (scale) form for being easy to remove.Optionally
Ground, the layer of repulsion are not removed actually, but are mixed in final products.Itself can be presented as that stiff dough is carbonized by the layer of repulsion
Object, nitride or oxide coating, soft abrasion-resistant material or can improve generation material expected characteristics any other function
It can property surface.In some cases, the superficial layer of repulsion can have composition, and undergo cooling scheme, this can solidify
Unsetting layer is generated on material surface.These structures for repelling surface can produce improvement relevant to following (but being not limited to these)
Characteristic: improved corrosion resistance, anticorrosion stress-resistant cracking, resistance to crack initiation, bulk strength, wearability, emissivity, reflectivity,
And magnetic susceptibility.
By removing or repelling pollutant, several situations may be implemented.With receiving for undesired pollutant reaction or combination
Rice corpuscles/micro particles or surface covering can participate in solidification in identical phase or independent solid phase.The nanoparticle of reaction/micro-
Rice corpuscles or surface covering can be ostracised during curing.The part present in the nanoparticle/micro particles or coating or
When chosen elements and pollutant reaction or combination, these parts or element can mix and/or repel.
In some embodiments, functionalized surfaces react formation lower material of fusing point compared with basis material when heated
Material, such as passes through eutectic reaction.Functionalized surfaces can be selected from the material for causing fusing in particle surface with lower section powdered reaction, or
In the partial volume of lower section powder.It can choose heat source such as laser or electron beam, so that energy density is sufficiently high to cause table
Face reaction, and will not be completely melt all functionalized powder.This causes to induce uniform liquid-phase sintering at particle surface.
When freezing, structure has characteristic microstructure, the pericentral different components of instruction raw material powder and nucleation mode,
After undergoing similar heat treatment, microstructure is similar to raw material powder.The structure can standardize later or undergo post-processing,
To increase density or improve characteristic.
Another possible reaction is the material expansion of peritectic reaction, the fusing of one or more of them component, and this fusing
It dissipates and enters the second nanoparticle or micro particles, to form alloy solid.Then the new alloy solid, which can serve as, is mutually nucleated
Center, or can limit and just be melted at particle edge.
, may be challenging in nanoparticle incorporation fusing metal when nanoparticle surface has thin oxide layer,
Because liquid metals is typically unable to fully wetting oxide.This can cause nanoparticle to be pulled to bath surface.A kind of gram
The mode for taking the oxide skin(coating) on nanoparticle and related Problem of Wettability is that nanometer is formed in situ during forming melting tank
Particle.This can be realized as follows: be formed with the element for forming intermetallic compound by a kind of component with matrix alloy
Nanoparticle starts, while avoiding nanoparticle dissolution in the melt.Alternatively, it can be used and decompose at elevated temperatures
Binary compound nanoparticle, such as hydride or nitride, because decomposition reaction can eliminate any oxidation on nanoparticle
Beyond the region of objective existence shell.
As described above, surface functionalization can be designed as reacting, and repel the surface of melting tank.Using increasing material
In the embodiment of manufacture, layer structure can be designed.In some embodiments, gradual building storey and hatching can be heated,
So that each subsequent melting enough long-times in pond of heating, to repel subsequent exclusion layer, thus generate have external squame and
Repelling in the construction of material has construction few or without observable layering.In other embodiments, it is particularly possible to
It is generated using those and repels the functional material on surface or wish heating and the hatching program of material to generate with stratiform most
The composite construction of finished product.Depending on construction parameter, these layer structures that can be randomly oriented or design can be used for producing
It is raw that there is the material for significantly improving characteristic.
Can with the microstructure of design structure, wherein for expected purpose selection three-dimensional network in characteristic size (for example,
The distance between nanoparticle node) and target composition.Similarly, layered composite structure can be designed, wherein for being expected
Purpose selects characteristic size (for example, thickness degree or interfloor distance) and target composition.
Note that repelling surface is not that generation layer structure institute is required.Functionalized surfaces can be on basic powder surface
Initial position relative to them is relatively fixed.As previously mentioned, during fusing, these functionalized surfaces can be served as
Nucleation site;However, be not absorbed into melt, they can previously occupied by powder surface and nucleation is caused in unfused position
Effect.The result is that the acinose texture developed towards center by surface nucleation source.This can produce for basis material
The composite construction of the design of characteristic enhancing.In general, this mechanism can be by controlling the position for solidifying control and wishing content
It sets.
In the increasing material manufacturing of titanium alloy, the microcosmic knot of Micro texture problem induced anisotropic of the succeeding layer of metal is melted
Structure, and therefore induced anisotropic architectural characteristic.Stable ceramic nanoparticle, which is dispersed in can produce in cured layer, to be had
The grain structure of isotropism feature, the grain structure are stable in heat cycles repeatedly.Example is attached to Ti-6Al-
Stable refractory ceramics nanoparticle on 4V micro particles powder surface, such as Al2O3Or TiCN, then fusing, solidification, then
When next layer of powder is reheated when top is melted.Ceramic nanoparticle can induce little crystal grain to be nucleated, and prevent in hot ladder
Degree side is upwardly formed coarse grain.
It is contemplated that obtaining any solidification of main degree of functionality from the surface functionalization of dusty material in the scope of the invention
Control method.Other control methods may include above-mentioned various control type.Method combination example including the use of repel surface,
Internal-response and emissivity control.For example, wherein functionalised materials are selected as to molten using increasing material manufacturing processing component
Solution reacts the insoluble material to be formed and repel fusing pool surface in surface.The repulsion material can have low transmitting in turn
Rate (any other laser emission of reflection), to reduce local heating, and coolant solidifies rapidly to control.Resulting structures
It is the material with the controlled solidification structure with low-launch-rate surface covering.
In some embodiments, solid-state is the three-dimensional microstructures containing these nanoparticles and/or micro particles, these
Nanoparticle and/or micro particles are distributed across the solid-state as content.
In some embodiments, solid-state is the layered microstructure containing one or more layers, this one or more layers include this
A little nanoparticles and/or micro particles.
This method, which may further include, generates a kind of structure by one or more technologies selected from the group below, the group by with
Lower composition: increasing material manufacturing, injection-molded, compacting and sintering, capacitor discharge sintering and spark plasma sintering.The present invention
A kind of solid objects or article are provided, the solid objects or article include the structure generated in this way.
Some modifications provide a kind of structure generated by increasing material manufacturing by functionalised powder.Functionalised powder (has and receives
Rice corpuscles/micro particles or surface covering) it can mix in final structure.In some embodiments, nanoparticle/micro particles
Or surface covering is ostracised, to generate squame.The squame can not be in conjunction with the structure.In some embodiments, should
Squame combines the structure, or can not otherwise be easily removed.This may be advantageous, and such as provide structure enhancing-for example
The ceramic particle of repulsion can add stiff dough for final structure.Nanoparticle/the micro particles or surface covering of repulsion can be with shapes
At multilayer materials, wherein each layer has different compositions.In some embodiments, the nanoparticle of repulsion/micron grain
Son or surface covering form spatial scalability composition in structural body.Three-dimensional construction can also be formed in final microstructure.
Some modifications provide a kind of solid objects or article, and the solid objects or article include at least one solid phase, this is extremely
A kind of few solid phase (i) includes dusty material as mentioned, or (ii) is originated from the liquid form of dusty material as mentioned.Example
Such as, which can form the 0.25wt% to 100wt% of solid objects or article, as the about 1wt% of solid objects or article,
5wt%, 10wt%, 25wt%, 50wt% or 75wt%.
Other modifications provide a kind of solid objects or article, and the solid objects or article include continuous solid phase and distribution time
And the continuous solid phase nanoparticle and/or micro particles content three-dimensional network, wherein the three-dimensional network prevent, hinder,
Or redirect dislocation motion in the solid objects or article.
In some embodiments, nanoparticle and/or micro particles content are evenly distributed through continuous solid phase.Example
Such as, the nanoparticle and/or micro particles content can be by solid objects or the about 0.1wt% to about 50wt% of article, such as
About 1wt%, 2wt%, 5wt%, 10wt%, 15wt%, 20wt%, 25wt%, 30wt%, 35wt%, 40wt% or 45wt%
Concentration exist.
In some embodiments, optical element is incorporated in system.For example, particle surface (or be present on powder particle
The surface of nanoparticle or micro particles) it can be reacted with element selected from the group below generation surface, the group consisting of:
Hydrogen, oxygen, carbon, nitrogen, boron, sulphur, and combinations thereof.For example, can carry out reacting with hydrogen, to form metal hydride.Optionally, should
Particle or particle coating further include salt, carbon, organic additive, inorganic additive, or combinations thereof.Some embodiments use phase
To inert carbide, they are mixed under rapid melting and cured situation (in incorporation steel).
Usually there is no restriction for the method for the dusty material of production surface functionalization, and may include immersion deposition, heavy without electricity
Product, gas phase coating, solution/suspension are coated with the particle with or without organic ligand, by mixing using electrostatic force and/or
Van der Waals force is attached particle, etc..U.S. Patent Application No. 14/720,757 (submission on May 23rd, 2015), United States Patent (USP) Shen
Please number 14/720,756 (submission on May 23rd, 2015) and U.S. Patent Application No. 14/860,332 (mention on September 21st, 2015
Hand over), it is each jointly owned with the assignee of present patent application, it is incorporated herein by reference hereby.These disclosure contents are one
The method being applied to certain materials involved in a little embodiments on micron powder.
For example, described in 332, coating can apply in the following manner such as U.S. Patent Application No. 14/860: using
Immersion deposition in ionic liquid, by carrying out chemistry displacement for high noble metal of arranging in order from the metal salt solution of coating metal
It is deposited on the substrate with the low noble metal with more negative electricity of arranging in order.This method is without external electrical field or other reduction
Agent, respectively as standard plating or electroless deposition.These metals can be selected from the group, which is made up of: aluminium, zirconium, titanium,
Zinc, nickel, cobalt copper, silver, gold, palladium, platinum, rhodium, titanium, molybdenum, uranium, niobium, tungsten, tin, lead, tantalum, chromium, iron, indium, rhenium, ruthenium, osmium, iridium and its group
Conjunction or alloy.
In some embodiments, organic ligand can be reacted on metal.Organic ligand can be selected from the group, the group by with
Lower composition: aldehyde, alkane, alkene, silicone, polyalcohol, poly- (acrylic acid), poly- (quaternary ammonium salt), poly- (alkylamine) including maleic anhydride
Or poly- (alkyl carboxylic acid) of the copolymer of itaconic acid, poly- (aziridine), poly- (propyleneimine), poly- (Vinylimdozoline), poly-
(trialkyl vinyl benzyl ammonium salt), poly- (carboxymethyl cellulose), poly- (D- or L-lysine), poly(L-glutamic acid), (L- days poly-
Aspartic acid), poly- (glutamic acid), heparin, dextran sulfate, l- carrageenan, pentosulfate, mannan sulfate, sulfuric acid
Chondroitin, and combinations thereof or derivative.
Reactive metal can be selected from the group, which is made up of: alkali metal, alkaline-earth metal, aluminium, silicon, titanium, zirconium, hafnium,
Zinc, and combinations thereof or alloy.In some embodiments, reactive metal be selected from aluminium, magnesium or containing greater than 50at% aluminium and/or
The alloy of magnesium.
The some possible powder metallurgy processing technologies that can be used include but is not limited to hot pressing, low pressure sintering, extrusion, gold
Belong to injection-molded and increasing material manufacturing.
In various embodiments, finished article can have from 0% to about 75%, such as from about 5%, 10%, 20%, 30%,
40%, 50%, 60% or 70% porosity.The porosity can be originated from particle (for example, hollow shape) in space and
Particle it is outer and between both spaces.Overall porosity considers both porosity sources.
Finished article can be selected from the group, which is made up of: sintering structure, coating, weld filler, blank, ingot,
Net shape part, near net-shaped component, and combinations thereof.The article can be by the inclusion of the technique of one or more technologies selected from the group below
By the reactive metal production being coated with, which is made up of: hot pressing, cold pressing, sintering, extrusion, injection-molded, increasing material manufacturing,
Electron-beam melting, selective laser sintering, pressureless sintering, and combinations thereof.
In some embodiments of the invention, the pellet melting of coating is together to form continuously or semi-continuously material.Such as
Intended by this specification, " melting ", which is broadly interpreted that, refers to that wherein particle is at least partly combined, engaged, poly-
Knot or any mode otherwise combined.Many known technologies can be used for pellet melting together.
In various embodiments, melting is accomplished by the following way: sintering, heat treatment, pressure treatment, heat/pressure of combination
Power processing, Electromagnetic Treatment, fusing/solidification, (cold) welding of contact, solution combustion synthesis, SHS process, is consolidated at electric treatment
State double decomposition, or combinations thereof.
" sintering ", which is broadly interpreted that, to be referred to through heat and/or the solid block of pressure initiation material without melting entire block
Change to the method for liquefaction point.Atom in material diffuses through the boundary of particle, by these pellet meltings together and generate one
A solid piece.Sintering temperature is typically lower than the fusing point of material.In some embodiments, using liquid state sintered, it is some of but
Not every volume is in liquid.
When using sintering or when another heat treatment, heat or energy can be by electric current, electromagnetic energy, chemical reaction (including ions
Or the formation of covalent bond), electrochemical reaction, pressure, or combinations thereof provide.Can provide heat for cause chemical reaction (for example,
To overcome activation energy), for improving kinetics, it is used for transfer reaction equilibrium state, or for adjusting reaction network distribution
State.
The some possible powder metallurgy processing technologies that can be used include but is not limited to hot pressing, sintering, high pressure low temperature burning
Knot, extrusion, metal injection-molding and increasing material manufacturing.
Sintering technology can be selected from the group, which is made up of: radiant heating, induction, spark plasma sintering, micro-
Wave heating, capacitor discharge sintering, and combinations thereof.Sintering can gas such as air or inert gas (such as Ar, He or
CO2) in the presence of or in reducing atmosphere (such as H2Or CO) in carry out.
Various sintering temperatures or temperature range can be used.Sintering temperature can be about or below about 100 DEG C, 200 DEG C,
300 DEG C, 400 DEG C, 500 DEG C, 600 DEG C, 700 DEG C, 800 DEG C, 900 DEG C or 1000 DEG C.
Sintering temperature is preferably less than reactive metal fusion temperature.In some embodiments, sintering temperature can be lower than
Highest alloy melting temperature, and can be further below minimum alloy melting temperature.In certain embodiments, sintering temperature can
In the range of the fusing point of selected alloy.In some embodiments, sintering temperature can be lower than the eutectic melting of particle alloy
Temperature.
It under peritectoid decomposition temperature, rather than melts, metal alloy resolves into another solid chemical compound and liquid.One
In a little embodiments, sintering temperature can be lower than the peritectoid decomposition temperature of metal alloy.In some embodiments, if there is multiple
Eutectic melting or peritectoid decomposition temperature, then sintering temperature can be lower than all these critical-temperatures.
In some embodiments for being related to the aluminium alloy used in micro particles, sintering temperature is preferably selected to low
In about 450 DEG C, 460 DEG C, 470 DEG C, 480 DEG C, 490 DEG C or 500 DEG C.The decomposition temperature of eutectic Al-base alloy is typically in 400-600
(Belov et al., Multicomponent Phase Diagrams:Applications for Commercial within the scope of DEG C
Aluminum Alloys [multicomponent phasor: the application of business aluminium alloy], Elsevier [Elsevier], 2005), the patent
Application is incorporated herein by reference hereby.
The solid article can be produced by technique selected from the group below, which is made up of: hot pressing, cold pressing and sintering,
Extrusion, injection-molded, increasing material manufacturing, electron-beam melting, selective laser sintering, pressureless sintering, and combinations thereof.The solid article
It can be such as coating, coating precursor, substrate, blank, ingot, net shape part, near net-shaped component or another object.
Example
The production of example 1:AlSi10Mg-WC functionally graded metal matrix matter nanocomposite.
In this example, functionally graded metal matrix matter nanometer is produced with AlSi10Mg alloy and tungsten carbide (WC) nanoparticle
Composite material.Originating AlSi10Mg alloy has 10wt% silicon (Si), 0.2wt%-0.45wt% magnesium (Mg) and in addition to impurity (example
Such as Fe and Mn) except remaining aluminium (Al) proximate composition.The density of tungsten carbide is 15.6g/cm3, and AlSi10Mg's is close
Degree is 2.7g/cm3.Tungsten carbide nanoparticle has the typical particle diameter of 15nm to 250nm.
Tungsten carbide nanoparticle is assembled on AlSi10Mg alloy powder.The material is solid under the compaction force of 300MPa
Knot, and then melted 1 hour at 700 DEG C in induction heater.Resulting materials (Figure 10) divide according to WC nanoparticle
Cloth shows functionally gradient.Figure 10 is the cross section (side of gained AlSi10Mg-WC functionally graded metal matrix matter nanocomposite
View) SEM image.
This is the example that the mutually separation high-density tungsten carbide nanoparticle of density-driven is separated to aluminium alloy substrate base.Ingot
The spontaneous bottom for being separated to melt of WC nanoparticle that the fusing of material causes density to be higher than AlSi10Mg;It is lower than with density
The gap of AlSi10Mg is spontaneous to be separated at the top of melt.The induction melting of predistribution ingot maintains the integrality of WC nanoparticle
And dispersibility, and reacting between nanoparticle and AlSi10Mg matrix is alleviated, to prevent the significant attached of nanoparticle
It is poly-.
The production of example 2:AlSi10Mg-WC master alloy metal matrix nanocomposite.
In this example, multiple with AlSi10Mg alloy and tungsten carbide (WC) nanoparticle production master alloy metal matrix nanometer
Condensation material.
Functionally graded metal matrix matter nanocomposite is produced according to example 1 first.Material shown in Figure 10 is female conjunction
The precursor of gold.According to Figure 10, tungsten carbide nanoparticle is preferentially located in the bottom of (functionally gradient) towards the structure.This is also similar
In the schematic diagram of Fig. 6.Contain little or no tungsten carbide nanoparticle towards the AlSi10Mg alloy (metal matrix phase) at top.
Material desired by the master alloy is lower layer's phase, and the tungsten carbide nanoparticle containing higher volumes is distributed in AlSi10Mg phase.
Then by the AlSi10Mg alloy (metal matrix phase) labeled as " AlSi " and lower layer's phase labeled as " AlSi+WC "
Separation.Resulting materials are master alloy metal matrix nanocomposites.Figure 11 is gained AlSi10Mg-WC master alloy metal matrix
The SEM image of the cross section (side view) of the microstructure of nanocomposite.It is deposited in high-volume fractional nanocomposite
It is accumulated in equally distributed WC nano-particle network without significant nanoparticle.
The master alloy metal matrix nanometer of the AlSiMg alloy of this hard reinforced phase with tungsten carbide nanoparticle is multiple
Condensation material example is demonstrated uses pre-dispersed ingot in the phase separation of density-driven.By mutually separating, WC and metal
The total volume fraction of matrix increases from pre-dispersed ingot.
The limitation of cost, availability and aspect of performance hinders progress of the metal-matrix composite in multiple industries.
Variant of the invention provides a kind of approach of effective, low cost manufacture metal matrix nanocomposite.This method is led to
Being enabled with property has the system of reinforcing material and metal-matrix composite component in many different applications with high-performance
Potentiality manufacture.
For example, business application includes high-wear-resistant alloy system, creep resistant alloy, with the high temperature conjunction for improving mechanical property
Golden, high thermal gradient application, radiation hardness alloy, high conductivity and high abrasion injection mold, the turbine disk, automobile and aviation exhaust system
Component and nuclear screening.The present invention provides the Near net shape casting with the object of complex surface, keeps on designed surface
Functionally gradient enhancing.The mutually separation of density-driven in casting can lead to thick functionally gradient product.
Other specific applications may include gear application, and wherein functionally gradient is used as Surface hardened layer;Work with hard surface
Plug, for improving abrasion and thermal behavior;It is highly conductive, wear resistant tools;Rotary fixing device, such as axis and coupler;Engine valve;
The cast structure of light metal;Highly conductive structural material;Wear-resistant material;Impact surface;Creep resistant material;Resistant material;And height
Conductive metal.
In this detailed description, multiple embodiment and attached drawing are referred to, this hair is shown by diagramatic way in the accompanying drawings
Bright specific illustrative embodiment.Abundant detailed description has been done to enable those skilled in the art to reality to these embodiments
The present invention is trampled, and it is to be understood that can be modified by those skilled in the art to disclosed various embodiments.
When the above method and step indicate that certain events are occurred with certain sequence, those of ordinary skill in the art be will recognize that
It is modification according to the present invention to the sequence and such modification that can modify certain steps.In addition, can be simultaneously when possible
Certain steps are performed simultaneously during row, and sequence executes certain steps.
Cited all publications, patent and patent application are incorporated in their entirety in this specification
Herein, it has specifically and individually been proposed herein just as each publication, patent or patent application.
Above-described embodiment, modification and attached drawing should provide the instruction of practicability and versatility of the invention.This is not being departed from
In the case where the spirit and scope of invention, it can also utilize and other implementations of all feature and advantage set forth herein are not provided
Example.Such modifications and variations are considered in the scope of the present invention being defined by the claims.
Claims (29)
1. a kind of master alloy metal matrix nanocomposite, which includes metal-base
Matter phase and the first reinforced phase containing the first nanoparticle, wherein first nanoparticle has and the metal-matrix phase
Different compositions.
2. master alloy metal matrix nanocomposite as described in claim 1, wherein the master alloy metal matrix nanometer
Composite material has cast microstructure.
3. master alloy metal matrix nanocomposite as described in claim 1, wherein the metal-matrix phase and described
One reinforced phase respectively spreads the master alloy metal matrix nanocomposite dispersion.
4. master alloy metal matrix nanocomposite as described in claim 1, wherein the metal-matrix phase and described
One reinforced phase is arranged in the master alloy metal matrix nanocomposite with layered configuration, wherein the layered configuration includes
At least first layer comprising first nanoparticle and at least second layer comprising the metal-matrix phase.
5. master alloy metal matrix nanocomposite as described in claim 1, is selected from wherein the metal-matrix mutually contains
The element of the following group, the group are made up of: Al, Mg, Ni, Fe, Cu, Ti, V, Si, and combinations thereof.
6. master alloy metal matrix nanocomposite as described in claim 1, wherein first nanoparticle contains choosing
From the compound of the following group, which is made up of: metal, ceramics, cermet, intermetallic alloy, oxide, carbide, nitrogen
Compound, boride, polymer, carbon, and combinations thereof.
7. master alloy metal matrix nanocomposite as described in claim 1, wherein first nanoparticle have from
About 1 nanometer to about 1000 nanometers of average grain diameter.
8. master alloy metal matrix nanocomposite as described in claim 1, wherein the nanocomposite contain from
The metal-matrix phase of about 10wt% to about 99.9wt%.
9. master alloy metal matrix nanocomposite as described in claim 1, wherein the nanocomposite contain from
First nanoparticle of about 0.1wt% to about 10wt%.
10. master alloy metal matrix nanocomposite as described in claim 1, the nanocomposite further include
The second nanoparticle in first reinforced phase and/or the second reinforced phase.
11. master alloy metal matrix nanocomposite as described in claim 1, wherein the master alloy metal matrix nanometer
Composite material is present in at least one 100 microns or larger sized object.
12. a kind of master alloy metal matrix nanocomposite, the master alloy metal matrix nanocomposite include containing Al,
The metal-matrix phase of Si and Mg and reinforced phase containing W and C.
13. master alloy metal matrix nanocomposite as claimed in claim 12, wherein the metal-matrix mutually contains aluminium
Alloy AlSi10Mg.
14. master alloy metal matrix nanocomposite as claimed in claim 12, wherein the reinforced phase contains tungsten carbide
(WC)。
15. master alloy metal matrix nanocomposite as claimed in claim 12, wherein the nanocomposite has
Cast microstructure.
16. a kind of method for preparing master alloy metal matrix nanocomposite, which comprises
(a) provide include metalliferous micro particles and nanoparticle ingot composition, wherein the nano particle with/
Or it is physically located on the surface of the micro particles, and wherein the nanoparticle spreads the ingot composition with three
Dimension construction consolidation;
(b) the ingot composition is melted to form melt, wherein the melt separation is at including the metalliferous micron grain
The first sub phase and the second phase comprising the nanoparticle;
(c) solidify the melt to obtain metal matrix nanocomposite, have through the nanocomposite extremely
The concentration gradient of the nanoparticle of a few dimension;And
(d) compared with the rest part of the metal matrix nanocomposite, removing a part contains to be received described in low concentration
Thus the metal matrix nanocomposite of rice corpuscles generates master alloy metal matrix nanocomposite.
17. the method described in claim 16, wherein the micro particles contain element selected from the group below, the group is by with the following group
At: Al, Mg, Ni, Fe, Cu, Ti, V, Si, and combinations thereof.
18. the method described in claim 16, wherein the nanoparticle contains compound selected from the group below, the group is by following
Composition: metal, ceramics, cermet, intermetallic alloy, oxide, carbide, nitride, boride, polymer, carbon and its
Combination.
19. the method described in claim 16, wherein the micro particles contain Al, Si and Mg, and the wherein nanometer
Particle contains tungsten carbide (WC).
20. the method described in claim 16, wherein step (b) further comprises compacting, sintering, mixing, dispersion, stirs and rub
Wipe welding, extrusion, bonding, capacitor discharge sintering, casting, or combinations thereof.
21. the method described in claim 16, wherein step (b) includes keeping effective stay time to cause the melt
The separation of first phase and the density-driven of second phase.
22. the method described in claim 16, wherein step (b) includes being exposed to the melt selected from gravity, centrifugation, machine
Tool, electromagnetism, or combinations thereof external force.
23. the method described in claim 16, wherein step (c) includes the directional solidification of the melt.
24. the method described in claim 16, wherein the metal matrix nanocomposite in step (c) has casting
Microstructure.
25. the method described in claim 16, wherein the concentration gradient of first nanoparticle is at least 100 microns
Length scale in be present in the metal matrix nanocomposite.
26. the method described in claim 16, wherein the metal-matrix phase and first reinforced phase are set with layered configuration
It sets in the metal matrix nanocomposite, wherein the layered configuration includes at least first comprising the nanoparticle
Layer and at least second layer comprising the metal-matrix phase.
27. the method described in claim 16, wherein step (d) includes processing, ablation, reaction, dissolution, evaporation, selectivity
Fusing, or combinations thereof.
28. the method described in claim 16, wherein it is nano combined to provide two different master alloy metal matrixs for step (d)
Material.
29. the method described in claim 16, wherein the master alloy metal matrix nanocomposite has casting microcosmic
Structure.
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